Media recording device with remote graphic user interface

ABSTRACT

An apparatus for processing digital media signals, comprising a digital processor for controlling the apparatus; a graphic user interface, having a wireless remote control providing a command input to the processor; a network interface for transmitting digital information from the processor to a remote location over a communications network, the information identifying a digital media signal for desired reproduction based, at least in part, on an input received from the remote control; and an output, controlled by, and local to, the processor, for transferring the desired digital media signals for reproduction thereof.

The present application is a continuation of U.S. patent application Ser. No. 10/162,079 filed Jun. 3, 2002, now U.S. Pat. No. 6,640,145, which is a continuation of U.S. patent application Ser. No. 09/241,135 filed Feb. 1, 1999, now U.S. Pat. No. 6,400,996. The present application is a continuation-in-part of U.S. patent application Ser. No. 09/260,802 (copending) filed Mar. 2, 1999, which is a continuation of U.S. patent application Ser. No. 07/812,805, filed Dec. 23, 1991, now U.S. Pat. No. 5,903,454.

A portion of the disclosure of this patent document and appendices contain material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of this patent document or the patent disclosure, as it appears in the U.S. Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.

FIELD OF THE INVENTION

The present invention relates to the field of adaptive systems, and more particularly systems and methods which are adaptive to a human user input and/or a data environment, as well as applications for such systems and methods. More particularly, embodiments of the invention involve, for example, consumer electronics, personal computers, control systems, and professional assistance systems.

BACKGROUND OF THE INVENTION

The prior art is rich in various systems and methods for data analysis, as well as various systems and methods relating to useful endeavors. In general, most existing systems and methods provide concrete functions, which have a defined response to a defined stimulus. Such systems, while embodying the “wisdom” of the designer, have a particular shortcoming in that their capabilities are static.

Intelligent or learning systems are also known. These systems are limited by the particular paradigm employed, and rarely are the learning algorithms general. In fact, while the generic theory and systems which learn are well known, the application of such systems to particular problems requires both a detailed description of the problem, as well as knowledge of the input and output spaces. Even once these factors are known, a substantial tuning effort may be necessary to enable acceptable operation.

Therefore, the present invention builds upon the prior art, which defines various problems to be addressed, intelligent systems and methods, tuning paradigms and user interfaces. Therefore, as set forth below, and in the attached appendix of references (including abstracts), incorporated herein by reference, a significant number of references detail fundamental technologies which may be improved according to the present invention, or incorporated together to form a part of the present invention. To the some extent, these technologies are disclosed and are expressly incorporated herein by reference to avoid duplication of prior art teachings. However, the disclosure herein is not meant to be limiting as to the knowledge of a person of ordinary skill in the art. Recitation hereinbelow of these teachings or reference to these teachings is not meant to imply that the inventors hereof were necessarily in any way involved in these references, nor that the particular improvements and claimed inventions recited herein were made or conceived after the publication of these references. Thus, prior art cited herein is intended to (1) disclose information related to the application published before the filing hereof; (2) define the problem in the art to which the present invention is directed, (3) define prior art methods of solving various problems also addressed by the present invention; (4) define the state of the art with respect to methods disclosed or referenced herein; and/or (5) detail technologies used to implement methods or apparatus in accordance with the present invention.

Human Interface

Aspects of the present invention provide an advanced user interface. The subject of man-machine interfaces has been studied for many years, and indeed the entire field of ergonomics and human factors engineering revolves-around optimization of human-machine interfaces. Typically, the optimization scheme optimizes the mechanical elements of a design, or seeks to provide a universally optimized interface. Thus, a single user interface is typically provided for a system. In fact, some systems provide a variety of interfaces, for example, novice, intermediate and advanced, to provide differing balances between available control and presented complexity. Further, adaptive and/or responsive human-machine computer interfaces are now well known. However, a typical problem presented is defining a self-consistent and useful (i.e., an improvement over a well-designed static interface) theory for altering the interface. Therefore, even where, in a given application, a theory exists, the theory is typically not generalizable to other applications. Therefore, one aspect of the present invention is to provide such a theory by which adaptive and/or responsive user interfaces may be constructed and deployed.

In a particular application, the user interface according to the present invention is applied to general-purpose-type computer systems, for example, personal computers. One aspect of the present invention thus relates to a programmable device that comprises a menu-driven interface in which the user enters information using a direct manipulation input device. Such a type of interface scheme is disclosed in Verplank, William L., “Graphics in Human-Computer Communication: Principles of Graphical User-Interface Design”, Xerox Office Systems. See the references cited therein: Foley, J. D., Wallace, V. L., Chan, P., “The Human Factor of Computer Graphics Interaction Techniques”, IEEE CG&A, November 1984, pp. 13–48; Koch, H., “Ergonomische Betrachtung von Schreibtastaturen”, Humane Production, 1, pp. 12–15 (1985); Norman, D. A., Fisher, D., “Why Alphabetic Keyboards Are Not Easy To Use: Keyboard Layout Doesn't Much Matter”, Human Factors 24(5), pp. 509–519 (1982); Perspectives: High Technology 2, 1985; Knowlton, K., “Virtual Pushbuttons as a Means of Person-Machine Interaction”, Proc. of Conf. Computer Graphics, Pattern Recognition and Data Structure, Beverly Hills, Calif., May 1975, pp. 350–352; “Machine Now Reads, enters Information 25 Times Faster Than Human Keyboard Operators”, Information Display 9, p. 18 (1981); “Scanner Converts Materials to Electronic Files for PCs”, IEEE CG&A, December 1984, p. 76; “New Beetle Cursor Director Escapes All Surface Constraints”, Information Display 10, p. 12, 1984; Lu, C., “Computer Pointing Devices: Living With Mice”, High Technology, January 1984, pp. 61–65; “Finger Painting”, Information Display 12, p. 18, 1981; Kraiss, K. F., “Neuere Methoden der Interaktion an der Schnittstelle Mensch-Maschine”, Z. F. Arbeitswissenschaft, 2, pp. 65–70, 1978; Hirzinger, G., Landzettel, K., “Sensory Feedback Structures for Robots with Supervised Learning”, IEEE Conf. on Robotics and Automation, St. Louis, March 1985; Horgan, H., “Medical Electronics”, IEEE Spectrum, January 1984, pp. 90–93.

A menu based remote control-contained display device is disclosed in Platte, Oberjatzas, and Voessing, “A New Intelligent Remote Control Unit for Consumer Electronic Device”, IEEE Transactions on Consumer Electronics, Vol. CE-31, No. 1. February 1985, 59–68.

A directional or direct manipulation-type sensor based infrared remote control is disclosed in Zeisel, Tomas, Tomaszewski, “An Interactive Menu-Driven Remote Control Unit for TV-Receivers and VC-Recorders”, IEEE Transactions on Consumer Electronics, Vol. 34, No. 3, 814–818 (1988), which relates to a control for programming with the West German Videotext system. This implementation differs from the Videotext programming system than described in Bensch, U., “VPV—VIDEOTEXT PROGRAMS VIDEORECORDER”, IEEE Transactions on Consumer Electronics, Vol. 34, No. 3, 788–792 (1988), which describes the system of Video Program System Signal Transmitters, in which the VCR is programmed by entering a code for the Video Program System signal, which is emitted by television stations in West Germany. Each separate program has a unique identifier code, transmitted at the beginning of the program, so that a user need only enter the code for the program, and the VCR will monitor the channel for the code transmission, and begin recording when the code is received, regardless of schedule changes. The Videotext Programs Recorder (VPV) disclosed does not intelligently interpret the transmission, rather the system reads the transmitted code as a literal label, without any analysis or determination of a classification of the program type.

Known manual input devices include the trackball, mouse, and joystick. In addition, other devices are known, including the so-called “J-cursor” or “mousekey” which embeds a two (x,y) or three (x,y,p) axis pressure sensor in a button conformed to a finger, present in a general purpose keyboard; a keyboard joystick of the type described in Electronic Engineering Times, Oct. 28, 1991, p. 62, “IBM Points a New Way”; a so-called “isobar” which provides a two axis input by optical sensors (θ, x), a two and one half axis (x, y, digital input) input device, such as a mouse or a “felix” device, infrared, acoustic, etc.; position sensors for determining the position of a finger or pointer on a display screen (touch-screen input) or on a touch surface, e.g., “GlidePoint” (ALPS/Cirque); goniometer input (angle position, such as human joint position detector), etc. Many of such suitable devices are summarized in Kraiss, K. F., “Alternative Input Devices For Human Computer Interaction”, Forschunginstitut Für Anthropotecahnik, Werthhoven, F. R. Germany. Another device, which may also be suitable is the GyroPoint, available from Gyration Inc., which provides 2-D or 3-D input information in up to six axes of motion: height, length, depth, roll, pitch and yaw. Such a device may be useful to assist a user in inputting a complex description of an object, by providing substantially more degrees of freedom sensing than minimally required by a standard graphic user interface. The many degrees of freedom available thus provide suitable input for various types of systems, such as “Virtual Reality” or which track a moving object, where many degrees of freedom and a high degree of input accuracy is required. The Hallpot, a device which pivots a magnet about a Hall effect sensor to produce angular orientation information, a pair of which may be used to provide information about two axes of displacement, available from Elweco, Inc, Willoughby, Ohio, may also be employed as an input device.

User input devices may be broken down into a number of categories: direct inputs, i.e. touch-screen and light pen; indirect inputs, i.e. trackball, joystick, mouse, touch-tablet, bar code scanner (see, e.g., Atkinson, Terry, “VCR Programming: Making Life Easier Using Bar Codes”), keyboard, and multi-function keys; and interactive input, i.e. Voice activation/instructions (see, e.g., Rosch, Winn L., “Voice Recognition: Understanding the Master's Voice”, PC Magazine, Oct. 27, 1987, 261–308); and eye tracker and data suit/data glove (see, e.g. Tello, Ernest R., “Between Man And Machine”, Byte, September 1988, 288–293; products of EXOS, Inc; Data Glove). Each of the aforementioned input devices has advantages and disadvantages, which are known in the art.

Studies suggest that a “direct manipulation” style of interface has advantages for menu selection tasks. This type of interface provides visual objects on a display screen, which can be manipulated by “pointing” and “clicking” on the them. For example, the popular Graphical User Interfaces (“GUIs”), such as Macintosh and Microsoft Windows, and others known in the art, use a direct manipulation style interface. A device such as a touch-screen, with a more natural selection technique, is technically preferable to the direct manipulation method. However, the accuracy limitations and relatively high cost make other inputs more commercially practical. Further, for extended interactive use, touchscreens are not a panacea for office productivity applications. In addition, the user must be within arms' length of the touch-screen display. In a cursor positioning task, Albert (1982) found the trackball to be the most accurate pointing device and the touch-screen to be the least accurate when compared with other input devices such as the light pen, joystick, data tablet, trackball, and keyboard. Epps (1986) found both the mouse and trackball to be somewhat faster than both the touch-pad and joystick, but he concluded that there were no significant performance differences between the mouse and trackball as compared with the touch-pad and joystick.

It is noted that in text-based applications, an input device that is accessible, without the necessity of moving the user's hands from the keyboard, may be preferred. Thus, for example, Electronic Engineering Times (EET), Oct. 28, 1991, p. 62, discloses a miniature joystick incorporated into the functional area of the keyboard. This miniature joystick has been successfully incorporated into a number of laptop computers.

The following references are also relevant to the interface aspects of the present invention:

-   Hoffberg, Linda I, “AN IMPROVED HUMAN FACTORED INTERFACE FOR     PROGRAMMABLE DEVICES: A CASE STUDY OF THE VCR” Master's Thesis,     Tufts University (Master of Sciences in Engineering Design,     November, 1990). -   “Bar Code Programs VCR”, Design News, Feb. 1, 1988, 26. -   “How to find the best value in VCRs”, Consumer Reports, March 1988,     135–141. -   “Low-Cost VCRs: More For Less”, Consumer Reports, March 1990,     168–172. -   “Nielsen Views VCRs”, Television Digest, Jun. 23, 1988, 15. -   “The Highs and Lows of Nielsen Homevideo Index”, Marketing & Media     Decisions, November 1985, 84–86+. -   “The Quest for ‘User Friendly’”, U.S. News & World Report, Jun.     13, 1988. 54–56. -   “The Smart House: Human Factors in Home Automation”, Human Factors     in Practice, December 1990, 1–36. -   “VCR, Camcorder Trends”, Television Digest, Vol. 29:16 (Mar. 20,     1989). -   “VCR's: A Look At The Top Of The Line”, Consumer Reports, March     1989, 167–170. -   “VHS Videocassette Recorders”, Consumer Guide, 1990, 17–20. -   Abedini, Kamran, “An Ergonomically-improved Remote Control Unit     Design”, Interface '87 Proceedings, 375–380. -   Abedini, Kamran, and Hadad, George, “Guidelines For Designing Better     VCRs”, Report No. IME 462, Feb. 4, 1987. -   Bensch, U., “VPV—VIDEOTEXT PROGRAMS VIDEORECORDER”, IEEE     Transactions on Consumer Electronics, 34(3):788–792. -   Berger, Ivan, “Secrets of the Universals”, Video, February 1989,     45–47+. -   Beringer, D. B., “A Comparative Evaluation of Calculator Watch Data     Entry Technologies: Keyboards to Chalkboards”, Applied Ergonomics,     December 1985, 275–278. -   Bier, E. A. et al. “MMM: A User Interface Architecture for Shared     Editors on a Single Screen,” Proceedings of the ACM Symposium on     User Interface Software and Technology, Nov. 11–13, 1991, p. 79. -   Bishop, Edward W., and Guinness, G. Victor Jr., “Human Factors     Interaction with Industrial Design”, Human Factors, 8(4):279–289     (August 1966). -   Brown, Edward, “Human Factors Concepts For Management”, Proceedings     of the Human Factors Society, 1973, 372–375. -   Bulkeley, Debra, “The Smartest House in America”, Design News, Oct.     19, 1987, 56–61. -   Card, Stuart K., “A Method for Calculating Performance times for     Users of Interactive Computing Systems”, IEEE, 1979, 653–658. -   Carlson, Mark A., “Design Goals for an Effective User Interface”.     Electro/82 Proceedings, 3/1/1–3/1/4. -   Carlson, Mark A., “Design Goals for an Effective User Interface”.     Human Interfacing with Instruments, Session 3. -   Carroll, Paul B., “High Tech Gear Draws Cries of “Uncle”, Wall     Street Journal, Apr. 27, 1988, 29. -   Cobb, Nathan, “I don't get it”, Boston Sunday Globe Magazine, Mar.     25, 1990, 23–29. -   Davis, Fred, “The Great Look-and-Feel Debate”, A+, 5:9–11 (July     1987). -   Dehning, Waltraud, Essig Heidrun, and Maass, Susanne, The Adaptation     of Virtual Man-Computer Interfaces to User Requirements in Dialogs,     Germany: Springer-Verlag, 1981. -   Ehrenreich, S. L., “Computer Abbreviations—Evidence and Synthesis”,     Human Factors, 27(2):143–155 (April 1985). -   Friedman, M. B., “An Eye Gaze Controlled Keyboard”, Proceedings of     the 2nd International Conference on Rehabilitation Engineering,     1984, 446–447. -   Gilfoil, D., and Mauro, C. L., “Integrating Human Factors and     Design: Matching Human Factors Methods up to Product     Development”, C. L. Mauro Assoc., Inc., 1–7. -   Gould, John D., Boies, Stephen J., Meluson, Antonia, Rasammy,     Marwan, and Vosburgh, Ann Marie, “Entry and Selection Methods For     Specifying Dates”. Human Factors, 32(2):199–214 (April 1989). -   Green, Lee, “Thermo Tech: Here's a common sense guide to the new     thinking thermostats”, Popular Mechanics, October 1985, 155–159. -   Grudin, Jonathan, “The Case Against User Interface Consistency”, MCC     Technical Report Number ACA-HI-002-89, January 1989. -   Harvey, Michael G., and Rothe, James T., “VideoCassette Recorders:     Their Impact on Viewers and Advertisers”, Journal of Advertising,     25:19–29 (December/January 1985). -   Hawkins, William J., “Super Remotes”, Popular Science, February     1989, 76–77. -   Henke, Lucy L., and Donohue, Thomas R., “Functional Displacement of     Traditional TV Viewing by VCR Owners”, Journal of Advertising     Research, 29:18–24 (April–May 1989). -   Hoban, Phoebe, “Stacking the Decks”, New York, Feb. 16, 1987, 20:14. -   Howard, Bill, “Point and Shoot Devices”, PC Magazine, 6:95–97     (August 1987). -   Jane Pauley Special, NBC TV News Transcript, Jul. 17, 1990, 10:00     PM. -   Kolson, Ann, “Computer wimps drown in a raging sea of technology”,     The Hartford Courant, May 24, 1989, B1. -   Kreifeldt, J. G., “A Methodology For Consumer Product Safety     Analysis”, The 3rd National Symposium on Human Factors in Industrial     Design in Consumer Products, August 1982, 175–184. -   Kreifeldt, John, “Human Factors Approach to Medical Instrument     Design”, Electro/82 Proceedings, 3/3/1–3/3/6. -   Kuocheng, Andy Poing, and Ellingstad, Vernon S., “Touch Tablet and     Touch Input”, Interface '87, 327. -   Ledgard, Henry, Singer, Andrew, and Whiteside, John, Directions in     Human Factors for Interactive Systems, New York, Springer-Verlag,     1981. -   Lee, Eric, and MacGregor, James, “Minimizing User Search Time Menu     Retrieval Systems”, Human Factors, 27(2):157–162 (April 1986). -   Leon, Carol Boyd, “Selling Through the VCR”, American Demographics,     December 1987, 40–43. -   Long, John, “The Effect of Display Format on the Direct Entry of     Numerical Information by Pointing”, Human Factors, 26(1):3–17     (February 1984). -   Mantei, Marilyn M., and Teorey, Toby J., “Cost/Benefit Analysis for     Incorporating Human Factors in the Software Lifecycle”, Association     for Computing Machinery, 1988. -   Meads, Jon A., “Friendly or Frivolous”, Datamation, Apr. 1, 1988,     98–100. -   Moore, T. G. and Dartnall, “Human Factors of a Microelectronic     Product: The Central Heating Timer/Programmer”, Applied Ergonomics,     1983, 13(1):15–23. -   Norman, Donald A., “Infuriating By Design”, Psychology Today,     22(3):52–56 (March 1988). -   Norman, Donald A., The Psychology of Everyday Things, New York,     Basic Book, Inc. 1988. -   Platte, Hans-Joachim, Oberjatzas, Gunter, and Voessing, Walter, “A     New Intelligent Remote Control Unit for Consumer Electronic Device”,     IEEE Transactions on Consumer Electronics, Vol. CE-31(1):59–68     (February 1985). -   Rogus, John G. and Armstrong, Richard, “Use of Human Engineering     Standards in Design”, Human Factors, 19(1):15–23 (February 1977). -   Rosch, Winn L., “Voice Recognition: Understanding the Master's     Voice”, PC Magazine, Oct. 27, 1987, 261–308. -   Sarver, Carleton, “A Perfect Friendship”, High Fidelity, 39:42–49     (May 1989). -   Schmitt, Lee, “Let's Discuss Programmable Controllers”, Modern     Machine Shop, May 1987, 90–99. -   Schniederman, Ben, Designing the User Interface: Strategies for     Effective Human-Computer Interaction, Reading, Mass.,     Addison-Wesley, 1987. -   Smith, Sidney J., and Mosier, Jane N., Guidelines for Designing User     Interface Software, Bedford, Mass., MITRE, 1986. -   Sperling, Barbara Bied, Tullis Thomas S., “Are You a Better ‘Mouser’     or ‘Trackballer’? A Comparison of Cursor—Positioning Performance”,     An Interactive/Poster Session at the CHI+GI'87 Graphics Interface     and Human Factors in Computing Systems Conference. -   Streeter, L. A., Ackroff, J. M., and Taylor, G. A. “On Abbreviating     Command Names”, The Bell System Technical Journal, 62(6):1807–1826     (July/August 1983). -   Swanson, David, and Klopfenstein, Bruce, “How to Forecast VCR     Penetration”, American Demographic, December 1987, 44–45. -   Tello, Ernest R., “Between Man And Machine”, Byte, September     1988.288–293. -   Thomas, John, C., and Schneider, Michael L., Human Factors in     Computer Systems, New Jersey, Ablex Publ. Co., 1984. -   Trachtenberg, Jeffrey A., “How do we confuse thee? Let us count the     ways”, Forbes, Mar. 21, 1988, 159–160. -   Tyldesley, D. A., “Employing Usability Engineering in the     Development of Office Products”, The Computer Journal”,     31(5):431–436 (1988). -   Verplank, William L., “Graphics in Human-Computer Communication:     Principles of Graphical User-Interface Design”, Xerox Office     Systems. -   Voyt, Carlton F., “PLC's Learn New Languages”, Design News, Jan. 2,     1989, 78. -   Whitefield, A. “Human Factors Aspects of Pointing as an Input     Technique in Interactive Computer Systems”, Applied Ergonomics, June     1986, 97–104. -   Wiedenbeck, Susan, Lambert, Robin, and Scholtz, Jean, “Using     Protocol Analysis to Study the User Interface”, Bulletin of the     American Society for Information Science, June/July 1989, 25–26. -   Wilke, William, “Easy Operation of Instruments by Both Man and     Machine”. Electro/82 Proceedings, 3/2/1–3/2/4. -   Yoder, Stephen Kreider, “U.S. Inventors Thrive at Electronics Show”,     The Wall Street Journal, Jan. 10, 1990, B1. -   Zeisel, Gunter, Tomas, Philippe, Tomaszewski, Peter, “An Interactive     Menu-Driven Remote Control Unit for TV-Receivers and VC-Recorders”,     IEEE Transactions on Consumer Electronics, 34(3):814–818.

Agent Technologies

Presently well known human computer interfaces include so-called agent technology, in which the computer interface learns a task defined (inherently or explicitly) by the user and subsequently executes the task. Such systems are available from Firefly (www.firefly.com), and are commercially present in some on-line commerce systems, such as Amazon.com (www.amazon.com). See:

-   “ABI WHAP, Web Hypertext Applications Processor,”     http://alphabase.com/abi3/whapinfo.html#profiling, (1996, Jul. 11). -   “AdForce Feature Set”,     http://www.imgis.com/index.html/core/p2--2html (1997, Apr. 11). -   “IPRO,” http://www.ipro.com/, Internet profiles Corporation Home and     other Web Pages (1996, Jul. 11). -   “Media Planning is Redefined in a New Era of Online Advertising,” PR     Newswire, (1996, Feb. 5). -   “My Yahoo! news summary for My Yahoo! Quotes”, http://my.yahoo.com,     (1997, Jan. 27). -   “NetGravity Announces Adserver 2.1”,     http://www.netgravity.com/news/pressrel/launch21.html (1997, Apr.     11). -   “Netscape & NetGravity: Any Questions?”, http://www.netgravity.com/,     (1996, Jul. 11). -   “Network Site Main”,     http://www.doubleclick.net/frames/general/nets2set.htm (1997, Apr.     11). -   “Real Media,” http://www.realmedia.com/index.html, (1996, Jul. 11). -   “The Front Page”, http://live.excite.com/?aBb (1997, Jan. 27) and     (1997, Apr. 11). -   “The Pointcast Network,” http:/www.pointcast.com/, (1996, Spring). -   “The Power of PenPoint”, Can et al., 1991, p. 39, Chapter 13, pp.     258–260. -   “Welcome to Lycos,” http://www.lycos.com, (1997, Jan. 27). -   Abatemarco, Fred, “From the Editor”, Popular Science, September     1992, p. 4 -   Berniker, M., “Nielsen plans Internet Service,” Broadcasting &     Cable, 125(30):34 (1995, Jul. 24). -   Berry, Deanne, et al. In an Apr. 10, 1990 news release, Symantec     announced a new version of MORE (TM). -   Betts, M., “Sentry cuts access to naughty bits,” Computers and     Security, vol. 14, No. 7, p. 615 (1995). -   Boy, Guy A., Intelligent Assistant Systems, Harcourt Brace     Jovanovich, 1991, uses the term “Intelligent Assistant Systems”. -   Bussey, H. E., et al., “Service Architecture, Prototype Description,     and Network Implications of a Personalized Information Grazing     Service,” IEEE Multiple Facets of Integration Conference     Proceedings, vol. 3, No. Conf. 9, Jun. 3, 1990, pp. 1046–1053. -   Donnelley, J. E., “WWW media distribution via Hopewise Reliabe     Multicast,” Computer Networks and ISDN Systems, vol. 27, No. 6, pp.     81–788 (April, 1995). -   Edwards, John R., “Q&A: Integrated Software with Macros and an     Intelligent Assistant”, Byte Magazine, January 1986, vol. 11, Issue     1, pp. 120–122, critiques the Intelligent Assistant by Symantec     Corporation. -   Elofson, G. and Konsynski, B., “Delegation Technologies:     Environmental Scanning with Intelligent Agents”, Journal of     Management Information Systems, Summer 1991, vol. 8, Issue 1, pp.     37–62. -   Garretson, R., “IBM Adds ‘Drawing Assistant’ Design Tool to Graphics     Series”, PC Week, Aug. 13, 1985, vol. 2, Issue 32, p. 8. -   Gessler, S. and Kotulla A., “PDAs as mobile WWW browsers,” Computer     Networks and ISDN Systems, vol. 28, No. 1–2, pp. 53–59 (December     1995). -   Glinert-Stevens, Susan, “Microsoft Publisher: Desktop Wizardry”,PC     Sources, February, 1992, vol. 3, Issue 2, p. 357. -   Goldberg, Cheryl, “IBM Drawing Assistant: Graphics for the EGA”, PC     Magazine, Dec. 24, 1985, vol. 4, Issue 26, p. 255. -   Hendrix, Gary G. and Walter, Brett A., “The Intelligent Assistant:     Technical Considerations Involved in Designing Q&A's     Natural-language Interface”, Byte Magazine, December 1987, vol. 12,     Issue 14, p. 251. -   Hoffman, D. L. et al., “A New Marketing Paradigm for Electronic     Commerce,” (1996, Feb. 19), http://www2000.ogsm.vanderbilt.edu     novak/new.marketing.paradigm.html. -   Information describing BroadVision One-to-One Application System:     “Overview,” p. 1; Further Resources on One-To-One Marketing, p. 1;     BroadVision Unleashes the Power of the Internet with Personalized     Marketing and Selling, pp. 1–3; Frequently Asked Questions, pp. 1–3;     Products, p. 1; BroadVision One-To-One(.TM.), pp. 1–2; Dynamic     Command Center, p. 1; Architecture that Scales, pp. 1–2; Technology,     pp. 1; Creating a New Medium for Marketing and Selling BroadVision     One-To-One and the World Wide Web a White Paper, pp. 1–15;     http://www.broadvision.com (1996, January–March). -   Jones, R., “Digaital's World-Wide Web server: A case study,”     Computer Networks and ISDN Systems, vol. 27, No. 2, pp. 297–306     (November 1994). -   McFadden, M., “The Web and the Cookie Monster,” Digital Age, (1996,     Aug.). -   Nadoli, Gajanana and Biegel, John, “Intelligent Agents in the     Simulation of Manufacturing Systems”, Proceedings of the SCS     Multiconference on AI and Simulation, 1989. -   Nilsson, B. A., “Microsoft Publisher is an Honorable Start for DTP     Beginners”, Computer Shopper, February 1992, vol. 12, Issue 2, p.     426, evaluates Microsoft Publisher and Page Wizard. -   O' Connor, Rory J., “Apple Banking on Newton's Brain”, San Jose     Mercury News, Wednesday, Apr. 22, 1992. -   Ohsawa, I. and Yonezawa, A., “A Computational Model of an     Intelligent Agent Who Talks with a Person”, Research Reports on     Information Sciences, Series C, April 1989, No. 92, pp. 1–18. -   Pazzani, M. et al., “Learning from hotlists and coldlists: Towards a     WWW Information Filtering and Seeking Agent,” Proceedings     International Conference on Tools with Artificial Intelligence,     January 1995, pp. 492–495. -   Poor, Alfred, “Microsoft Publisher”, PC Magazine, Nov. 26, 1991,     vol. 10, Issue 20, p. 40, evaluates Microsoft Publisher. -   PRNewswire, information concerning the PointCast Network (PCN)     (1996, Feb. 13) p. 213. -   Raggett, D., “A review of the HTML+document format,” Computer     Networks and ISDN Systems, vol. 27, No. 2, pp. 35–145 (November     1994). -   Rampe, Dan, et al. In a Jan. 9, 1989 news release, Claris     Corporation announced two products, SmartForm Designer and SmartForm     Assistant, which provide “Intelligent Assistance”, such as custom     help messages, choice lists, and data-entry validation and     formatting. -   Ratcliffe, Mitch and Gore, Andrew, “Intelligent Agents take U.S.     Bows.”, MacWeek, Mar. 2, 1992, vol. 6, No. 9, p. 1. -   Sharif Heger, A. and Koen, B. V., “KNOWBOT: an Adaptive Data Base     Interface”, Nuclear Science and Engineering, February 1991, vol.     107, No. 2, pp. 142–157. -   Soviero, Marcelle M., “Your World According to Newton”, Popular     Science, September 1992, pp. 45–49. -   Upendra Shardanand, “Social Information Filtering for Music     Recommendation” September 1994, pp. 1–93, Massachusetts Institute of     Technology, Thesis. -   Weber, Thomas E., “Software Lets Marketers Target Web Ads,” The Wall     Street Journal, Apr. 21, 1997. -   Weiman, Liza and Moran, Tom, “A Step toward the Future”. Macworld,     August 1992, pp. 129–131. -   Yan, T. W. and Garcia-Molina, H., “SIFT-A Tool for Wide-Area     Information Dissemination,” Paper presented at the USENIX Technical     Conference, New Orleans, La. (1995, Jan.), pp. 177–186.

Industrial Controls

Industrial control systems are well known. Typically, a dedicated reliable hardware module controls a task using a conventional algorithm, with a low level user interface. These devices are programmable, and therfore a high level software program may be provided to translate user instructions into the low level commands, and to analyze any return data. See, U.S. Pat. No. 5,506,768, expressly incoporated herein by reference. See, also:

-   A. B. Corripio, “Tuning of Industrial Control Systems”, Instrument     Society of America, Research Triangle Park, N. C. (1990) pp. 65–81. -   C. J. Harris & S. A. Billings, “Self-Tuning and Adaptive Control:     Theory and Applications”, Peter Peregrinus LTD (1981) pp. 20–33. -   C. Rohrer & Clay Nesler, “Self-Tuning Using a Pattern Recognition     Approach”, Johnson Controls, Inc., Research Brief 228 (Jun. 13,     1986). -   D. E. Seborg, T. F. Edgar, & D. A. Mellichamp, “Process Dynamics and     Control”, John Wiley & Sons, NY (1989) pp. 294–307, 538–541. -   E. H. Bristol & T. W. Kraus, “Life with Pattern Adaptation”,     Proceedings 1984 American Control Conference, pp. 888–892, San     Diego, Calif. (1984). -   Francis Schied, “Shaum's Outline Series-Theory & Problems of     Numerical Analysis”, McGraw-Hill Book Co., NY (1968) pp. 236, 237,     243, 244, 261. -   K. J. Astrom and B. Wittenmark, “Adaptive Control”, Addison-Wesley     Publishing Company (1989) pp. 105–215. -   K. J. Astrom, T. Hagglund, “Automatic Tuning of PID Controllers”,     Instrument Society of America, Research Triangle Park, N. C. (1988)     pp. 105–132. -   R. W. Haines, “HVAC Systems Design Handbook”, TAB Professional and     Reference Books, Blue Ridge Summit, Pa. (1988) pp. 170–177. -   S. M. Pandit & S. M. Wu, “Timer Series & System Analysis with     Applications”, John Wiley & Sons, Inc., NY (1983) pp. 200–205. -   T. W. Kraus 7 T. J. Myron, “Self-Tuning PID Controller Uses Pattern     Recognition Approach”, Control Engineering, pp. 106–111, June 1984.

Pattern Recognition

Another aspect of some embodiments of the invention relates to signal analysis and complex pattern recognition. This aspect encompasses analysis of any data set presented to the system: internal, user interface, or the environment in which it operates. While semantic, optical and audio analysis systems are known, the invention is by no means limited to these types of data.

Pattern recognition involves examining a complex data set to determine similarities (in its broadest context) with other data sets, typically data sets which have been previously characterized. These data sets may comprise multivariate inputs, sequences in time or other dimension, or a combination of both multivariate data sets with multiple dimensions.

The following cited patents and publications are relevant to pattern recognition and control aspects of the present invention, and are herein expressly incorporated by reference:

U.S. Pat. No. 5,067,163, incorporated herein by reference, discloses a method for determining a desired image signal range from an image having a single background, in particular a radiation image such as a medical X-ray. This reference teaches basic image enhancement techniques.

U.S. Pat. No. 5,068,664, incorporated herein by reference, discloses a method and device for recognizing a target among a plurality of known targets, by using a probability based recognition system. This patent document cites a number of other references, which are relevant to the problem of image recognition:

-   Appriou, A., “Interet des theories de l'incertain en fusion de     donnees”, Colloque International sur le Radar Paris, 24–28 avril     1989. -   Appriou, A., “Procedure d'aide a la decision multi-informateurs.     Applications a la classification multi-capteurs de-cibles”,     Symposium de l'Avionics Panel (AGARD) Turquie, 25–29 avril 1988. -   Arrow, K. J., “Social choice and individual valves”, John Wiley and     Sons Inc. (1963). -   Bellman, R. E., L. A. Zadeh, “Decision making in a fuzzy     environment”, Management Science, 17(4) (December 1970). -   Bhatnagar, R. K., L. N. Kamal, “Handling uncertain information: a     review of numeric and non-numeric methods”, Uncertainty in     Artificial Intelligence, L. N. Kamal and J. F. Lemmer, Eds. (1986). -   Blair, D., R. Pollack, “La logique du choix collectif” Pour la     Science (1983). -   Chao, J. J., E. Drakopoulos, C. C. Lee, “An evidential reasoning     approach to distributed multiple hypothesis detection”, Proceedings     of the 20th Conference on decision and control, Los Angeles, Calif.,     December 1987. -   Dempster, A. P., “A generalization of Bayesian inference”, Journal     of the Royal Statistical Society, Vol. 30, Series B (1968). -   Dempster, A. P., “Upper and lower probabilities induced by a     multivalued mapping”, Annals of mathematical Statistics, no. 38     (1967). -   Dubois, D., “Modeles mathematiques de l'imprecis et de l'incertain     en vue d'applications aux techniques d'aide a la decision”, Doctoral     Thesis, University of Grenoble (1983). -   Dubois, D., N. Prade, “Combination of uncertainty with belief     functions: a reexamination”, Proceedings 9th International Joint     Conference on Artificial Intelligence, Los Angeles (1985). -   Dubois, D., N. Prade, “Fuzzy sets and systems-Theory and     applications”, Academic Press, New York (1980). -   Dubois, D., N. Prade, “Theorie des possibilites: application a la     representation des connaissances en informatique”, Masson, Paris     (1985). -   Duda, R. O., P. E. Hart, M. J. Nilsson, “Subjective Bayesian methods     for rule-based inference systems”, Technical Note 124-Artificial     Intelligence Center-SRI International. -   Fua, P. V., “Using probability density functions in the framework of     evidential reasoning Uncertainty in knowledge based systems”, B.     Bouchon, R. R. Yager, Eds. Springer Verlag (1987). -   Ishizuka, M., “Inference methods based on extended Dempster and     Shafer's theory for problems with uncertainty/fuzziness”, New     Generation Computing, 1:159–168 (1983), Ohmsha, Ltd, and Springer     Verlag. -   Jeffrey, R. J., “The logic of decision”, The University of Chicago     Press, Ltd., London (1983) (2nd Ed.). -   Kaufmann, A., “Introduction a la theorie des sous-ensembles flous”,     Vol. 1, 2 et 3-Masson-Paris (1975). -   Keeney, R. L., B. Raiffa, “Decisions with multiple objectives:     Preferences and value tradeoffs”, John Wiley and Sons, New York     (1976). -   Ksienski et al., “Low Frequency Approach to Target Identification”,     Proc. of the IEEE, 63(12):1651–1660 (December 1975). -   Kyburg, H. E., “Bayesian and non Bayesian evidential updating”.     Artificial Intelligence 31:271–293 (1987). -   Roy, B., “Classements et choix en presence de points de vue     multiples”, R.I.R.O.-2eme annee-no. 8, pp. 57–75 (1968). -   Roy, B., “Electre III: un algorithme de classements fonde sur une     representation floue des preferences en presence de criteres     multiples”, Cahiers du CERO, 20(1):3–24 (1978). -   Scharlic, A., “Decider sur plusieurs criteres. Panorama de l'aide a     la decision multicritere” Presses Polytechniques Romandes (1985). -   Shafer, G., “A mathematical theory of evidence”, Princeton     University Press, Princeton, N.J. (1976). -   Sugeno, M., “Theory of fuzzy integrals and its applications”, Tokyo     Institute of Technology (1974). -   Vannicola et al, “Applications of Knowledge based Systems to     Surveillance”, Proceedings of the 1988 IEEE National Radar     Conference, 20–21 April 1988, pp. 157–164. -   Yager, R. R., “Entropy and specificity in a mathematical theory of     Evidence”, Int. J. General Systems, 9–249-260 (1983). -   Zadeh, L. A., “Fuzzy sets as a basis for a theory of possibility”,     Fuzzy sets and Systems 1:3–28 (1978). -   Zadeh, L. A., “Fuzzy sets”, Information and Control, 8:338–353     (1965). -   Zadeh, L. A., “Probability measures of fuzzy events”, Journal of     Mathematical Analysis and Applications, 23:421–427 (1968).

U.S. Pat. No. 5,067,161, incorporated herein by reference, relates to a video image pattern recognition system, which recognizes objects in near real time.

U.S. Pat. Nos. 4,817,176 and 4,802,230, both incorporated herein by reference, relate to harmonic transform methods of pattern matching of an undetermined pattern to known patterns, and are useful in the pattern recognition method of the present invention. U.S. Pat. No. 4,998,286, incorporated herein by reference, relates to a harmonic transform method for comparing multidimensional images, such as color images, and is useful in the present pattern recognition methods.

U.S. Pat. No. 5,067,166, incorporated herein by reference, relates to a pattern recognition system, in which a local optimum match between subsets of candidate reference label sequences and candidate templates. It is clear that this method is useful in the pattern recognition aspects of the present invention. It is also clear that the interface and control system of the present invention are useful adjuncts to the method disclosed in U.S. Pat. No. 5,067,166.

U.S. Pat. No. 5,048,095, incorporated herein by reference, relates to the use of a genetic learning algorithm to adaptively segment images, which is an initial stage in image recognition. This patent has a software listing for this method. It is clear that this method is useful in the pattern recognition aspects of the present invention. It is also clear that the interface and control system of the present invention are useful adjuncts to the method disclosed in U.S. Pat. No. 5,048,095.

Fractal-Based Image Processing

Fractals are a relatively new field of science and technology that relate to the study of order and chaos. While the field of fractals is now very dense, a number of relevant principles are applicable. First, when the coordinate axes of a space are not independent, and are related by a recursive algorithm, then the space is considered to have a fractional dimensionality. One characteristic of such systems is that a mapping of such spaces tends to have self-similarity on a number of scales. Interestingly, natural systems have also been observed to have self-similarity over several orders of magnitude, although as presently believed, not over an unlimited range of scales. Therefore, one theory holds that images of natural objects may be efficiently described by iterated function systems (IFS), which provide a series of parameters for a generic formula or algorithm, which, when the process is reversed, is visually similar to the starting image. Since the “noise” of the expanded data is masked by the “natural” appearance of the result, visually acceptable image compression may be provided at relatively high compression ratios. This theory remains the subject of significant debate, and, for example, wavelet algorithm advocates claim superior results for a more general set of starting images. It is noted that, on a mathematical level, wavelets and fractal theories have some common threads.

According to a particular embodiment of the invention, the expression of an image as an ordered set of coefficients of an algorithm, wherein the coefficients relate to elements of defined variation in scale, and the resulting set of coefficients is related to the underlying image morphology, is exploited in order to provide a means for pattern analysis and recognition without requiring decompression to an orthogonal coordinate space.

U.S. Pat. Nos. 5,065,447, and 4,941,193, both incorporated herein by reference, relate to the compression of image data by using fractal transforms. These are discussed in detail below. U.S. Pat. No. 5,065,447 cites a number of references, relevant to the use of fractals in image processing:

-   U.S. Pat. No. 4,831,659. -   “A New Class of Markov Processes for Image Encoding”, School of     Mathematics, Georgia Inst. of Technology (1988), pp. 14–32. -   “Construction of Fractal Objects with Iterated Function Systems”,     Siggraph '85 Proceedings, 19(3):271–278 (1985). -   “Data Compression: Pntng by Numbrs”, The Economist, May 21, 1988. -   “Fractal Geometry-Understanding Chaos”, Georgia Tech Alumni     Magazine, p. 16 (Spring 1986). -   “Fractal Modelling of Biological Structures”, Perspectives in     Biological Dynamics and Theoretical Medicine, Koslow, Mandell,     Shlesinger, eds., Annals of New York Academy of Sciences, vol. 504,     179–194 (date unknown). -   “Fractal Modelling of Real World Images. Lecture Notes for Fractals:     Introduction, Basics and Perspectives”, Siggraph (1987). -   “Fractals—A Geometry of Nature”, Georgia Institute of Technology     Research Horizons, p. 9 (Spring 1986). -   A. Jacquin, “A Fractal Theory of Iterated Markov Operators with     Applications to Digital Image Coding ”, PhD Thesis, Georgia Tech,     1989. -   A. Jacquin, “Image Coding Based on a Fractal Theory of Iterated     Contractive Image Transformations ” p. 18, January 1992 (Vol 1     Issue 1) of IEEE Trans on Image Processing. -   A. Jacquin, ‘Fractal image coding based on a theory of iterated     contractive image transformations’, Proc. SPIE Visual Communications     and Image Processing, 1990, pages 227–239. -   A. E. Jacquin, ‘A novel fractal block-coding technique for digital     images’, Proc. ICASSP 1990. -   Baldwin, William, “Just the Bare Facts, Please”, Forbes Magazine,     Dec. 12, 1988. -   Barnsley et al., “A Better Way to Compress Images”, Byte Magazine,     January 1988, pp. 213–225. -   Barnsley et al., “Chaotic Compression”, Computer Graphics World,     November 1987. -   Barnsley et al., “Harnessing Chaos For Images Synthesis”, Computer     Graphics, 22(4):131–140 (August, 1988). -   Barnsley et al., “Hidden Variable Fractal Interpolation Functions”,     School of Mathematics, Georgia Institute of Technology, Atlanta, Ga.     30332, July, 1986. -   Barnsley, M. F., “Fractals Everywhere”, Academic Press, Boston,     Mass., 1988. -   Barnsley, M. F., and Demko, S., “Iterated Function Systems and The     Global Construction of Fractals”, Proc. R. Soc. Lond., A399:243–275     (1985). -   Barnsley, M. F., Ervin, V., Hardin, D., Lancaster, J., “Solution of     an Inverse Problem for Fractals and Other Sets”, Proc. Natl. Acad.     Sci. U.S.A., 83:1975–1977 (April 1986). -   Beaumont J M, “Image data compression using fractal techniques ”,     British Telecom Technological Journal 9(4):93–108 (1991). -   Byte Magazine, January 1988, supra, cites: -   D. S. Mazel, Fractal Modeling of Time-Series Data, PhD Thesis,     Georgia Tech, 1991. (One dimensional, not pictures). -   Derra, Skip, “Researchers Use Fractal Geometry”, Research and     Development Magazine, March 1988. -   Elton, J., “An Ergodic Theorem for Iterated Maps”, Journal of     Ergodic Theory and Dynamical Systems, 7 (1987). -   Fisher Y, “Fractal image compression ”, Siggraph 92. -   Fractal Image Compression Michael F. Barnsley and Lyman P. Hurd ISBN     0-86720-457–5, ca. 250 pp. -   Fractal Image Compression: Theory and Application, Yuval Fisher     (ed.), Springer Verlag, New York, 1995. ISBN number 0-387-94211-4. -   Fractal Modelling of Biological Structures, School of Mathematics,     Georgia Institute of Technology (date unknown). -   G. E. Oien, S. Lepsoy & T. A. Ramstad, ‘An inner product space     approach to image coding by contractive transformations’, Proc.     ICASSP 1991, pp 2773–2776. -   Gleick, James, “Making a New Science”, pp. 215, 239, date unknown. -   Graf S, “Barnsley's Scheme for the Fractal Encoding of Images ”,     Journal Of Complexity, V8, 72–78 (1992). -   Jacobs, E. W., Y. Fisher and R. D. Boss. “Image Compression: A study     of the Iterated Transform Method. Signal Processing 29, (1992)     25–263. -   M. Barnsley, L. Anson, “Graphics Compression Technology, SunWorld,     October 1991, pp. 42–52. -   M. F. Barnsley, A. Jacquin, F. Malassenet, L. Reuter & A. D. Sloan,     ‘Harnessing chaos for image synthesis’, Computer Graphics, vol 22 no     4 pp 131–140, 1988. -   M. F. Barnsley, A. E. Jacquin, ‘Application of recurrent iterated     function systems to images’, Visual Comm. and Image Processing, vol     SPIE-1001, 1988. -   Mandelbrot, B., “The Fractal Geometry of Nature”, W.H. Freeman &     Co., San Francisco, Calif., 1982, 1977. -   Monro D M and Dudbridge F, “Fractal block coding of images ”,     Electronics Letters 28(11):1053–1054 (1992). -   Monro D. M. & Dudbridge F. ‘Fractal approximation of image blocks’,     Proc ICASSP 92, pp. III: 485–488. -   Monro D. M. ‘A hybrid fractal transform’, Proc ICASSP 93, pp. V:     169–72. -   Monro D. M., Wilson D., Nicholls J. A. ‘High speed image coding with     the Bath Fractal Transform’, IEEE International Symposium on     Multimedia Technologies Southampton, April 1993. -   Peterson, Ivars, “Packing It In—Fractals . . . ”, Science News,     131(18):283–285 (May 2, 1987). -   S. A. Hollatz, “Digital image compression with two-dimensional     affine fractal interpolation functions ”, Department of Mathematics     and Statistics, University of Minnesota-Duluth, Technical Report     91-2. (a nuts-and-bolts how-to-do-it paper on the technique). -   Stark, J., “Iterated function systems as neural networks ”, Neural     Networks, Vol 4, pp 679–690, Pergamon Press, 1991. -   Vrscay, Edward R. “Iterated Function Systems: Theory, Applications,     and the Inverse Problem. Fractal Geometry and Analysis, J. Belair     and S. Dubuc (eds.) Kluwer Academic, 1991. 405–468.

U.S. Pat. No. 5,347,600, incorporated herein by reference, relates to a method and apparatus for compression and decompression of digital image data, using fractal methods. According to this method, digital image data is automatically processed by dividing stored image data into domain blocks and range blocks. The range blocks are subjected to processes such as a shrinking process to obtain mapped range blocks. The range blocks or domain blocks may also be processed by processes such as affine transforms. Then, for each domain block, the mapped range block which is most similar to the domain block is determined, and the address of that range block and the processes the blocks were subjected to are combined as an identifier which is appended to a list of identifiers for other domain blocks. The list of identifiers for all domain blocks is called a fractal transform and constitutes a compressed representation of the input image. To decompress the fractal transform and recover the input image, an arbitrary input image is formed into range blocks and the range blocks processed in a manner specified by the identifiers to form a representation of the original input image.

“Image Compression Using Fractals and Wavelets”, Final Report for the Phase II Contract Sponsored by the Office of Naval Research, Contract No. N00014-91-C-0117, Netrologic Inc., San Diego, Calif. (Jun. 2, 1993), relates to various methods of compressing image data, including fractals and wavelets. This method may also be applicable in pattern recognition applications. This reference provides theory and comparative analysis of compression schemes.

A fractal-processing method based image extraction method is described in Kim, D. H.; Caulfield. H. J.; Jannson, T.; Kostrzewski, A.; Savant, G, “Optical fractal image processor for noise-embedded targets detection”, Proceedings of the SPIE—The International Society for Optical Engineering, Vol. 2026, p. 144–9 (1993) (SPIE Conf: Photonics for Processors, Neural Networks, and Memories 12–15 July 1993, San Diego, Calif., USA). According to this paper, a fractal dimensionality measurement and analysis-based automatic target recognition (ATR) is described. The ATR is a multi-step procedure, based on fractal image processing, and can simultaneously perform preprocessing, interest locating, segmenting, feature extracting, and classifying. See also, Cheong, C. K.; Aizawa, K.; Saito, T.; Hatori, M., “Adaptive edge detection with fractal dimension”, Transactions of the Institute of Electronics. Information and Communication Engineers D-II, J76D-II(11):2459–63 (1993); Hayes, H. I.; Solka, J. L.; Priebe, C. E.; “Parallel computation of fractal dimension”, Proceedings of the SPIE—The International Society for Optical Engineering, 1962:219–30 (1993); Priebe, C. E.; Solka, J. L.; Rogers, G. W., “Discriminant analysis in aerial images using fractal based features”, Proceedings of the SPIE—The International Society for Optical Engineering, 1962:196–208(1993). See also, Anson, L., “Fractal Image Compression”, Byte, October 1993, pp. 195–202; “Fractal Compression Goes On-Line”, Byte, September 1993.

Methods employing other than fractal-based algorithms may also be used. See, e.g., Liu, Y., “Pattern recognition using Hilbert space”, Proceedings of the SPIE—The International Society for Optical Engineering, 1825:63–77 (1992), which describes a learning approach, the Hilbert learning. This approach is similar to Fractal learning, but the Fractal part is replaced by Hilbert space. Like the Fractal learning, the first stage is to encode an image to a small vector in the internal space of a learning system. The next stage is to quantize the internal parameter space. The internal space of a Hilbert learning system is defined as follows: a pattern can be interpreted as a representation of a vector in a Hilbert space. Any vectors in a Hilbert space can be expanded. If a vector happens to be in a subspace of a Hilbert space where the dimension L of the subspace is low (order of 10), the vector can be specified by its norm, an L-vector, and the Hernitian operator which spans the Hilbert space, establishing a mapping from an image space to the internal space P. This mapping converts an input image to a 4-tuple: t in P=(Norm, T, N, L-vector), where T is an operator parameter space, N is a set of integers which specifies the boundary condition. The encoding is implemented by mapping an input pattern into a point in its internal space. The system uses local search algorithm, i.e., the system adjusts its internal data locally. The search is first conducted for an operator in a parameter space of operators, then an error function delta (t) is computed. The algorithm stops at a local minimum of delta (t). Finally, the input training set divides the internal space by a quantization procedure. See also, Liu, Y., “Extensions of fractal theory”, Proceedings of the SPIE—The International Society for Optical Engineering, 1966:255–68(1993).

Fractal methods may be used for pattern recognition. See, Sadjadi, F., “Experiments in the use of fractal in computer pattern recognition”, Proceedings of the SPIE—The International Society for Optical Engineering, 1960:214–22(1993). According to this reference, man-made objects in infrared and millimeter wave (MMW) radar imagery may be recognized using fractal-based methods. The technique is based on estimation of the fractal dimensions of sequential blocks of an image of a scene and slicing of the histogram of the fractal dimensions computed by Fourier regression. The technique is shown to be effective for the detection of tactical military vehicles in IR, and of airport attributes in MMW radar imagery.

In addition to spatial self-similarity, temporal self-similarity may also be analyzed using fractal methods. See, Reusens, E., “Sequence coding based on the fractal theory of iterated transformations systems”, Proceedings of the SPIE—The International Society for Optical Engineering, 2094(pt.1):132–40(1993). This reference describes a scheme based on the iterated functions systems theory which relies on a 3D approach in which the sequence is adaptively partitioned. Each partition block can be coded either by using the spatial self similarities or by exploiting temporal redundancies.

Fractal compression methods may be used for video data for transmission. See, Hurtgen, B.; Buttgen, P., “Fractal approach to low rate video coding”, Proceedings of the SPIE—The International Society for Optical Engineering, 2094(pt.1):120–31(1993). This reference relates to a method for fast encoding and decoding of image sequences on the basis of fractal coding theory and the hybrid coding concept. The DPCM-loop accounts for statistical dependencies of natural image sequences in the temporal direction. Those regions of the original image where the prediction, i.e. motion estimation and compensation, fails are encoded using an advanced fractal coding scheme, suitable for still images, and whose introduction instead of the commonly used Discrete Cosine Transform (DCT)-based coding is advantageous especially at very low bit rates (8–64 kbit/s). In order to increase reconstruction quality, encoding speed and compression ratio, some additional features such as hierarchical codebook search and multilevel block segmentation may be employed. This hybrid technique may be used in conjunction with the present adaptive interface or other features of the present invention.

Fractal methods may be used to segment an image into objects having various surface textures. See, Zhi-Yan Xie; Brady, M., “Fractal dimension image for texture segmentation”, ICARCV '92. Second International Conference on Automation, Robotics and Computer Vision, p. CV-4.3/1–5 vol. 1, (1992). According to this reference, the fractal dimension and its change over boundaries of different homogeneous textured regions is analyzed and used to segment textures in infrared aerial images. Based on the fractal dimension, different textures map into different fractal dimension image features, such that there is smooth variation within a single homogeneous texture but sharp variation at texture boundaries. Since the fractal dimension remains unchanged under linear transformation, this method is robust for dismissing effects caused by lighting and other extrinsic factors. Morphology is the only tool used in the implementation of the whole process: texture feature extraction, texture segmentation and boundary detection. This makes possible parallel implementations of each stage of the process.

Rahmati, M.; Hassebrook, L. G., “Intensity- and distortion-invariant pattern recognition with complex linear morphology”, Pattern Recognition, 27 (4):549–68(1994) relates to a unified model based pattern recognition approach is introduced which can be formulated into a variety of techniques to be used for a variety of applications. In this approach, complex phasor addition and cancellation are incorporated into the design of filter(s) to perform implicit logical operations using linear correlation operators. These implicit logical operations are suitable to implement high level gray scale morphological transformations of input images. In this way non-linear decision boundaries are effectively projected into the input signal space yet the mathematical simplicity of linear filter designs is maintained. This approach is applied to the automatic distortion- and intensity-invariant object recognition problem. A set of shape operators or complex filters is introduced-which are logically structured into a filter bank architecture to accomplish the distortion and intensity-invariant system. This synthesized complex filter bank is optimally sensitive to fractal noise representing natural scenery. The sensitivity is optimized for a specific fractal parameter range using the Fisher discriminant. The output responses of the proposed system are shown for target, clutter, and pseudo-target inputs to represent its discrimination and generalization capability in the presence of distortion and intensity variations. Its performance is demonstrated with realistic scenery as well as synthesized inputs.

Sprinzak, J.; Werman, M., “Affine point matching”, Pattern Recognition Letters, 15(4):337–9(1994), relates to a pattern recognition method. A fundamental problem of pattern recognition, in general, is recognizing and locating objects within a given scene. The image of an object may have been distorted by different geometric transformations such as translation, rotation, scaling, general affine transformation or perspective projection. The recognition task involves finding a transformation that superimposes the model on its instance in the image. This reference proposes an improved method of superimposing the model.

Temporal Image Analysis

Temporal image analysis is a well known field. This field holds substantial interest at present for two reasons. First, by temporal analysis of a series of two dimensional images, objects and object planes may be defined, which provide basis for efficient yet general algorithms for video compression, such as the Motion Picture Experts Group (MPEG) series of standards. Second, temporal analysis has applications in signal analysis for an understanding and analysis of the signal itself.

U.S. Pat. No. 5,280,530, incorporated herein by reference, relates to a method and apparatus for tracking a moving object in a scene, for example the face of a person in videophone applications, comprises forming an initial template of the face, extracting a mask outlining the face, dividing the template into a plurality (for example sixteen) sub-templates, searching the next frame to find a match with the template, searching the next frame to find a match with each of the sub-templates, determining the displacements of each of the sub-templates with respect to the template, using the displacements to determine affine transform coefficients and performing an affine transform to produce an updated template and updated mask.

U.S. Pat. No. 5,214,504 relates to a moving video image estimation system, based on an original video image of time n and time n+1, the centroid, the principal axis of inertia, the moment about the principal axis of inertia and the moment about the axis perpendicular to the principal axis of inertia are obtained. By using this information, an affine transformation for transforming the original video image at time n to the original video image at time n+1 is obtained. Based on the infinitesimal transformation (A), {e^(At), and e^(A(t−1))} obtained by making the affine transformation continuous with regard to time is executed on the original video image at time n and time n+1. The results are synthesized to perform an interpolation between the frames. {e^((a(t−1))} is applied to the original video system time n+1. The video image after time n+1 is thereby protected.

U.S. Pat. No. 5,063,603, incorporated herein by reference, relates to a dynamic method for recognizing objects and image processing system therefor. This reference discloses a method of distinguishing between different members of a class of images, such as human beings. A time series of successive relatively high-resolution frames of image data, any frame of which may or may not include a graphical representation of one or more predetermined specific members (e.g., particular known persons) of a given generic class (e.g. human beings), is examined in order to recognize the identity of a specific member; if that member's image is included in the time series. The frames of image data may be examined in real time at various resolutions, starting with a relatively low resolution, to detect whether some earlier-occurring frame includes any of a group of image features possessed by an image of a member of the given class. The image location of a detected image feature is stored and then used in a later-occurring, higher resolution frame to direct the examination only to the image region of the stored location in order to (1) verify the detection of the aforesaid image feature, and (2) detect one or more other of the group of image features, if any is present in that image region of the frame being examined. By repeating this type of examination for later and later occurring frames, the accumulated detected features can first reliably recognize the detected image region to be an image of a generic object of the given class, and later can reliably recognize the detected image region to be an image of a certain specific member of the given class. Thus, a human identity recognition feature of the present invention may be implemented in this manner. Further, it is clear that this recognition feature may form an integral part of certain embodiments of the present invention. It is also clear that the various features of the present invention would be applicable as an adjunct to the various elements of the system disclosed in U.S. Pat. No. 5,063,603.

U.S. Pat. No. 5,067,160, incorporated herein by reference, relates to a motion-pattern recognition apparatus, having adaptive capabilities. The apparatus recognizes a motion of an object that is moving and is hidden in an image signal, and discriminates the object from the background within the signal. The apparatus has an image-forming unit comprising non-linear oscillators, which forms an image of the motion of the object in accordance with an adjacent-mutual-interference-rule, on the basis of the image signal. A memory unit, comprising non-linear oscillators, stores conceptualized meanings of several motions. A retrieval unit retrieves a conceptualized meaning close to the motion image of the object. An altering unit alters the rule, on the basis of the conceptualized meaning. The image forming unit, memory unit, retrieval unit and altering unit form a holonic-loop. Successive alterations of the rules by the altering unit within the holonic loop change an ambiguous image formed in the image forming unit into a distinct image. U.S. Pat. No. 5,067,160 cites the following references, which are relevant to the task of discriminating a moving object in a background:

-   U.S. Pat. No. 4,710,964. -   Shimizu et al, “Principle of Holonic Computer and Holovision”,     Journal of the Institute of Electronics, Information and     Communication, 70(9):921–930 (1987). -   Omata et al, “Holonic Model of Motion Perception”, IEICE Technical     Reports, Mar. 26, 1988, pp. 339–346. -   Ohsuga et al, “Entrainment of Two Coupled van der Pol Oscillators by     an External Oscillation”, Biological Cybernetics, 51:225–239 (1985).

U.S. Pat. No. 5,065,440, incorporated herein by reference, relates to a pattern recognition apparatus, which compensates for, and is thus insensitive to pattern shifting, thus being useful for decomposing an image or sequence of images, into various structural features and recognizing the features. U.S. Pat. No. 5,065,440 cites the following references, incorporated herein by reference, which are also relevant to the present invention: U.S. Pat. Nos. 4,543,660, 4,630,308, 4,677,680, 4,809,341, 4,864,629, 4,872,024 and 4,905,296.

Recent analyses of fractal image compression techniques have tended to imply that, other than in special circumstances, other image compression methods are “better” than a Barnsley-type image compression system, due to the poor performance of compression processors and lower than expected compression ratios. Further, statements attributed to Barnsley have indicated that the Barnsley technique is not truly a “fractal” technique, but rather a vector quantization process which employs a recursive library. Nevertheless, these techniques and analyses have their advantages. As stated hereinbelow, the fact that the codes representing the compressed image are hierarchical represents a particular facet exploited by the present invention.

Another factor which makes fractal methods and analysis relevant to the present invention is the theoretical relation to optical image processing and holography. Thus, while such optical systems may presently be cumbersome and economically unfeasible, and their implementation in software models slow, these techniques nevertheless hold promise and present distinct advantages.

Biometric Analysis

Biometric analysis comprises the study of the differences between various organisms, typically of the same species. Thus, the intraspecies variations become the basis for differentiation and identification. In practice, there are many applications for biometric analysis systems, for example in security applications, these allow identification of a particular human.

U.S. Pat. No. 5,055,658, incorporated herein by reference, relates to a security system employing digitized personal characteristics, such as voice. The following references are cited:

-   “Voice Recognition and Speech Processing”, Elektor Electronics,     September 1985, pp. 56–57. -   Naik et al., “High Performance Speaker Verification.”, ICASSP 86,     Tokyo, CH2243-4/86/0000-0881, IEEE 1986, pp. 881–884. -   Shinan et al., “The Effects of Voice Disguise.”, ICASSP 86, Tokyo,     CH2243-4/86/0000-0885, IEEE 1986, pp. 885–888.

Parts of this system relating to speaker recognition may be used to implement a voice recognition system of the present invention for determining an actor or performer in a broadcast.

Neural Networks

Neural networks are a particular type of data analysis tool. There are characterized by the fact that the network is represented by a set of “weights”, which are typically scalar values, which are derived by a formula which is designed to reduce the error between the a data pattern representing a known state and the network's prediction of that state. These networks, when provided with sufficient complexity and an appropriate training set, may be quite sensitive and precise. Further, the data pattern may be arbitrarily complex (although the computing power required to evaluate the output will also grow) and therefore these systems may be employed for video and other complex pattern analysis.

U.S. Pat. No. 5,067,164, incorporated herein by reference, relates to a hierarchical constrained automatic learning neural network for character recognition, and thus represents an example of a trainable neural network for pattern recognition, which discloses methods which are useful for the present invention. This patent cites various references of interest:

-   U.S. Pat. Nos. 4,760,604, 4,774,677 and 4,897,811. -   LeCun, Y., Connectionism in Perspective, R. Pfeifer, Z. Schreter, F.     Fogelman, L. Steels, (Eds.), 1989, “Generalization and Network     Design Strategies”, pp. 143–55. -   LeCun, Y., et al., “Handwritten Digit Recognition: Applications of     Neural.”, IEEE Comm. Magazine, pp. 41–46 (November 1989). -   Lippmann, R. P., “An Introduction to Computing with Neural Nets”,     IEEE ASSP Magazine, 4(2):4–22 (April 1987). -   Rumeihart, D. E., et al., Parallel Distr. Proc.: Explorations in     Microstructure of Cognition, vol. 1, 1986, “Learning Internal     Representations by Error Propagation”, pp. 318–362.

U.S. Pat. Nos. 5,048,100, 5,063,601 and 5,060,278, all incorporated herein by reference, also relate to neural network adaptive pattern recognition methods and apparatuses. It is clear that the methods of U.S. Pat. Nos. 5,048,100, 5,060,278 and 5,063,601 may be used to perform the adaptive pattern recognition functions of the present invention. More general neural networks are disclosed in U.S. Pat. Nos. 5,040,134 and 5,058,184, both incorporated herein be reference, which provide background on the use of neural networks. In particular, U.S. Pat. No. 5,058,184 relates to the use of the apparatus in information processing and feature detection applications.

U.S. Pat. No. 5,058,180, incorporated herein by reference, relates to neural network apparatus and method for pattern recognition, and is thus relevant to the intelligent pattern recognition functions of the present invention. This patent cites the following documents of interest:

-   U.S. Pat. Nos. 4,876,731 and 4,914,708. -   Carpenter, G. A., S. Grossberg, “The Art of Adaptive Pattern     Recognition by a Self-Organizing Neural Network,” IEEE Computer,     March 1988, pp. 77–88. -   Computer Visions, Graphics, and Image Processing 1987, 37:54–115. -   Grossberg, S., G. Carpenter, “A Massively Parallel Architecture for     a Self-Organizing Neural Pattern Recognition Machine,”     Computer-Vision, Graphics, and Image Processing (1987, 37, 54–115),     pp. 252–315. -   Gullichsen E., E. Chang, “Pattern Classification by Neural Network:     An Experiment System for Icon Recognition,” ICNN Proceeding on     Neural Networks, March 1987, pp. IV-725–32. -   Jacket, L. D., H. P. Graf, J. S. Denker, D. Henderson and I. Guyon,     “An Application of Neural Net Chips: Handwritten Digit Recognition,”     ICNN Proceeding, 1988, pp. 11–107-15. -   Lippman, R. P., “An Introduction to Computing with Neural Nets,”     IEEE ASSP Magazine, April 1987, pp. 4–22. -   Pawlicki, T. F., D. S. Lee, J. J. Hull and S. N. Srihari, “Neural     Network Models and their Application to Handwritten Digit     Recognition,” ICNN Proceeding, 1988, pp. II-63–70.

Chao, T.-H.; Hegblom, E.; Lau, B.; Stoner, W. W.; Miceli, W. J., “Optoelectronically implemented neural network with a wavelet preprocessor”, Proceedings of the SPIE—The International Society for Optical Engineering, 2026:472–82(1993), relates to an optoelectronic neural network based upon the Neocognitron paradigm which has been implemented and successfully demonstrated for automatic target recognition for both focal plane array imageries and range-Doppler radar signatures. A particular feature of this neural network architectural design is the use of a shift-invariant multichannel Fourier optical correlation as a building block for iterative multilayer processing. A bipolar neural weights holographic synthesis technique was utilized to implement both the excitatory and inhibitory neural functions and increase its discrimination capability. In order to further increase the optoelectronic Neocognitron's self-organization processing ability, a wavelet preprocessor was employed for feature extraction preprocessing (orientation, size, location, etc.). A multichannel optoelectronic wavelet processor using an e-beam complex-valued wavelet filter is also described.

Neural networks are important tools for extracting patterns from complex input sets. These systems do not require human comprehension of the pattern in order to be useful, although human understanding of the nature of the problem is helpful in designing the neural network system, as is known in the art. Feedback to the neural network is integral to the training process. Thus, a set of inputs is mapped to a desired output range, with the network minimizing an “error” for the training data set. Neural networks may differ based on the computation of the “error”, the optimization process, the method of altering the network to minimize the error, and the internal topology. Such factors are known in the art.

Optical Pattern Recognition

Optical image processing holds a number of advantages. First, images are typically optical by their nature, and therefore processing by this means may (but not always) avoid a data conversion. Second, many optical image processing schemes are inherently or easily performed in parallel, improving throughput. Third, optical circuits typically have response times shorter than electronic circuits, allowing potentially short cycle times. While many optical phenomena may be modeled using electronic computers, appropriate applications for optical computing, such as pattern recognition, hold promise for high speed in systems of acceptable complexity.

U.S. Pat. No. 5,060,282, incorporated herein by reference, relates to an optical pattern recognition architecture implementing the mean-square error correlation algorithm. This method allows an optical computing function to perform pattern recognition functions. U.S. Pat. No. 5,060,282 cites the following references, which are relevant to optical pattern recognition:

-   Kellman, P., “Time Integrating Optical Signal Processing”. Ph. D.     Dissertation. Stanford University, 1979, pp. 51–55. -   Molley, P., “Implementing the Difference-Squared Error Algorithm     Using An Acousto-Optic Processor”, SPIE, 1098:232–239, (1989). -   Motley, P., et al., “A High Dynamic Range Acousto-Optic Image     Correlator for Real-Time Pattern Recognition”, SPIE, 938:55–65     (1988). -   Psaltis, D., “Incoherent Electro-Optic Image Correlator”, Optical     Engineering, 23(1):12–15 (Jan./February 1984). -   Psaltis, D., “Two-Dimensional Optical Processing Using     One-Dimensional Input Devices”, Proceedings of the IEEE,     72(7):962–974 (July 1984). -   Rhodes, W., “Acousto-Optic Signal Processing: Convolution and     Correlation”, Proc. of the IEEE, 69(1):65–79 (January 1981). -   Vander Lugt, A., “Signal Detection By Complex Spatial Filtering”,     IEEE Transactions On Information Theory, IT-10, 2:139–145 (April     1964).

U.S. Pat. Nos. 5,159,474 and 5,063,602, expressly incorporated herein by reference, also relate to optical image correlators. Also of interest is Li, H. Y., Y. Qiao and D. Psaltis, Applied Optics (April, 1993). See also, Bains, S., “Trained Neural Network Recognizes Faces”, Laser Focus World, June, 1993, pp. 26–28; Bagley, H. & Sloan, J., “Optical Processing: Ready For Machine Vision?”, Photonics Spectra, August 1993, pp. 101–106.

Optical pattern recognition has been especially applied to two dimensional patterns. In an optical pattern recognition system, an image is correlated with a set of known image patterns represented on a hologram, and the product is a pattern according to a correlation between the input pattern and the provided known patterns. Because this is an optical technique, it is performed nearly instantaneously, and the output information can be reentered into an electronic digital computer through optical transducers known in the art. Such a system is described in Casasent, D., Photonics Spectra, November 1991, pp. 134–140. The references cited therein provide further details of the theory and practice of such a system: Lendaris, G. G., and Stanely, G. L., “Diffraction Pattern Sampling for Automatic Target Recognition”, Proc. IEEE 58:198–205 (1979); Ballard, D. H., and Brown. C. M., Computer Vision, Prentice Hall. Englewood Cliffs, N.J. (1982); Optical Engineering 28:5 (May 1988) (Special Issue on product inspection); Richards J., and Casasent, D., “Real Time Hough Transform for Industrial Inspection” Proc. SPIE Technical Symposium, Boston 1989 1192:2–21 (1989); Maragos, P., “Tutorial Advances in Morphological Image Processing” Optical Engineering 26:7:623–632 (1987); Casasent, D., and Tescher, A., Eds., “Hybrid Image and Signal Processing II”, Proc. SPIE Technical Symposium, April 1990, Orlando Fla. 1297 (1990); Ravichandran, G. and Casasent, D., “Noise and Discrimination Performance of the MINACE Optical Correlation Filter”, Proc. SPIE Technical Symposium, April 1990, Orlando Fla., 1471 (1990); Weshsler, H. Ed., “Neural Nets For Human and Machine Perception”, Academic Press, New York (1991).

By employing volume holographic images, the same types of paradigms may be applied to three dimensional images.

Query by Image Content

Query by image content, a phrase coined by IBM researchers, relates to a system for retrieving image data stored in a database on the basis of the colors, textures, morphology or objects contained within the image. Therefore, the system characterizes the stored images to generate a metadata index, which can then be searched. Unindexed searching is also possible.

A number of query by image content systems are known, including both still and moving image systems, for example from IBM (QBIC), Apple (Photobook), Belmont Research Inc. (Steve Gallant), BrainTech Inc.; Center for Intelligent Information Retrieval (Umass Amherst), Virage, Inc., Informix Software, Inc. (Illustra), Islip Media, Inc., Magnifi, Numinous Technologies, Columbia University VisualSeek/WebSeek (Chang et al., John R. Smith), Monet (CWI and UvA), Visual Computing Laboratory, UC San Diego (ImageGREP, White and Jain). See also, ISO/IEC MPEG-7 literature.

See, Jacobs, et al., “Fast Multiresolution Image Querying”, Department of Computer Science, University of Washington, Seattle Wash.

U.S. Pat. No. 5,655,117, expressly incorporated herein by reference, relates to a method and apparatus for indexing multimedia information streams for content-based retrieval. See also:

-   Gong et al, “An Image Database System with Content Capturing and     Fast Image Indexing Abilities”, PROC of the International Conference     on Multimedia Computing and Systems, pp. 121–130 May 19, 1994. -   Hongjiang, et al., Digital Libraries, “A Video Database System for     Digital Libraries”, pp. 253–264, May 1994. -   S. Abe and Y. Tonomura, Systems and Computers in Japan, vol. 24, No.     7, “Scene Retrieval Method Using Temporal Condition Changes”, pp.     92–101, 1993. -   Salomon et al, “Using Guides to Explore Multimedia Databases”, PROC     of the Twenty-Second Annual Hawaii International Conference on     System Sciences. vol. IV, 3–6 January 1989, pp. 3–12 vol. 4. Jan. 6,     1989. -   Stevens, “Next Generation Network and Operating System Requirements     for Continuous Time Media”, in Herrtwich (Ed.), Network and     Operating System Support for Digital Audio and Video, pp. 197–208,     November 1991.

U.S. Pat. No. 5,606,655, expressly incorporated herein by reference, relates to a method for representing contents of a single video shot using frames. The method provides a representative frame (Rframe) for a group of frames in a video sequence, selecting a reference frame from the group of frames and storing the reference frame in a computer memory. This system defines a peripheral motion tracking region along an edge of the reference frame and successively tracks movement of boundary pixels in the tracking region, symbolizing any of the length of the shot and the presence of any caption. See, also:

-   “A Magnifier Tool for Video Data”, Mills et al., Proceedings of ACM     Computer Human Interface (CHI), May 3–7, 1992, pp. 93–98. -   “A New Family of Algorithms for Manipulating Compressed Images”,     Smith et al., IEEE Computer Graphics and Applications, 1993. -   “Anatomy of a Color Histogram”, Novak et al., Proceeding of Computer     Vision and Pattern Recognition, Champaign, Ill., June 1992, pp.     599–605. -   “Automatic Structure Visualization for Video Editing”, Ueda et al.,     InterCHI'93 Conference Proceedings, Amsterdam, The Netherlands,     24–29 April 1993, pp. 137–141. -   “Automatic Video Indexing and Full-Video Search for Object     Appearances”, Nagasaka et al., Proceedings of the IFIP TC2/WG2.6     Second Working Conference on Visual Database Systems, North Holland,     Sep. 30-Oct. 3, 1991, pp. 113–127. -   “Color Indexing”, Swain et al., International Journal of Computer     Vision, vol. 7, No. 1, 1991, pp. 11–32. -   “Content Oriented Visual Interface Using Video Icons for Visual     Database Systems”, Tonomura et al., Journal of Visual Languages and     Computing (1990) 1, pp. 183–198. -   “Developing Power Tools for Video Indexing and Retrieval”, Zhang et     al., Proceedings of SPIE Conference on Storage and Retrieval for     Image and Video Databases, San Jose, Calif., 1994. -   “Image Information Systems: Where Do We Go From Here?”, Chang et     al., IEEE Transactions on Knowledge and Data Engineering, vol. 4,     No. 5, October 1992, pp. 431–442. -   “Image Processing on Compressed Data for Large Video Databases”,     Arman et al., Proceedings of First ACM International Conference on     Multimedia, Anaheim, Calif., 1–6 August 1993, pp. 267–272. -   “Image Processing on Encoded Video Sequences”, Arman et al., ACM     Multimedia Systems Journal, to appear 1994. -   “Impact: An Interactive Natural-Motion-Picture Dedicated Multimedia     Authoring System”, Ueda et al., Proceedings of Human Factors in     Computing Systems (CHI 91), New Orleans, La., Apr. 27–May 2, 1991,     pp. 343–350. -   “MPEG: A Video Compression Standard for Multimedia Applications”, Le     Gall, Communications of the ACM, vol. 34, No. 4, April 1991, pp.     47–58. -   “News On-Demand for Multimedia Networks”, Miller et al., ACM     International Conference on Multimedia, Anaheim, Calif., 1–6, August     1993, pp. 383–392. -   “Overview of the px64 kbit/s Video Coding Standard”, Liou,     Communications of the ACM, vol. 34, No. 4, April 1991, pp. 60–63. -   “Pattern Recognition by Moment Invariants”, Hu et al., Proc. IRE,     vol. 49, 1961, p. 1428. -   “Pattern Recognition Experiments in the Mandala/Cosine Domain”, Hsu     et al., IEEE Transactions on Pattern Analysis and Machine     Intelligence, vol. PAMI-5, No. 5, September 1983, pp. 512–520. -   “The JPEG Still Picture Compression Standard”, Wallace,     Communications of the ACM, vol. 34, No. 4, April 1991, pp. 31–44. -   “The Revised Fundamental Theorem of Moment Invariants”, Reiss, IEEE     Transactions on Pattern Analysis and Machine Intelligence, vol. 13,     No. 8, August 1991, pp. 830–834. -   “VideoMAP and VideoSpaceIcon: Tools for Anatomizing Video Content”,     Tonomura et al., Inter CHI'93 Conference Proceedings, Amsterdam, The     Netherlands, 24–29 April, 1993, pp. 131–136. -   “Visual Pattern Recognition by Moment Invariants”, IRE Trans.     Inform. Theory, vol. 8, February 1962, pp. 179–187. -   “Watch —Grab —Arrange —See: Thinking with Motion Images via Streams     and Collages”, Elliott, Ph.D. Thesis, MIT, February 1993. -   Book entitled Digital Image Processing, by Gonzalez et al.,     Addison-Wesley, Readings, Mass., 1977. -   Book entitled Digital Picture Processing by Rosenfeld et al.,     Academic Press, Orlando, Fla., 1982. -   Book entitled Discrete Cosine Transform—Algorithms, Advantages,     Applications, by Rao et al., Academic Press, Inc., 1990. -   Book entitled Sequential Methods in Pattern Recognition and Machine     Learning, Fu, Academic, NY, N.Y. 1968. -   C.-C. J. Kuo (ed), “Multimedia Storage and Archiving Systems”, SPIE     Proc. Vol. 2916 (Nov. 18–Nov. 22, 1996).

U.S. Pat. No. 5,600,775, expressly incorporated herein by reference, relates to a method and apparatus for annotating full motion video and other indexed data structures. U.S. Pat. No. 5,428,774, expressly incorporated herein by reference relates to a system of updating an index file of frame sequences so that it indexes non-overlapping motion image frame sequences. U.S. Pat. No. 5,550,965, expressly incorporated herein by reference, relates to a method and system for operating a data processor to index primary data in real time with iconic table of contents. U.S. Pat. No. 5,083,860, expressly incorporated herein by reference, relates to a method for detecting change points in motion picture images. U.S. Pat. No. 5,179,449, expressly incorporated herein by reference, relates to a scene boundary detecting apparatus. See also:

-   “A show and tell of the QBIC technology—Query By Image Content     (QBIC)”, IBM QBIC Almaden web site, pp. 1–4. -   “Chaos & Non-Linear Models in Economics”. -   “Chaos Theory in the Financial Markets. Applying Fractals, Fuzzy     Logic, Genetic Algorithms”. -   “Evolutionary Economics & Chaos Theory”. -   “Four Eyes”, MIT Media Lab web site; pp. 1–2. -   “Frequently asked questions about visual information retrieval”,     Virage Incorporated web site; pp. 1–3. -   “IBM Ultimedia Manager 1.1 and Clinet Search”, IBM software web     site, pp. 1–4. -   “Image Detection and Registration”, Digital Image Processing, Pratt,     Wiley, New York, 1991. -   “Jacob Methodology” @     http://WWCSAI.diepa.unipa.it/research/projects/jacob/jacob-method.html. -   “Market Analysis. Applying Chaos Theory to Invstment & Economics”. -   “Photobook”, MIT Media Lab web site; Aug. 7, 1996; pp. 1–2. -   “Profiting from Chaos. Using Chaos Theory for Market Timing, Stock     Selection & Option”. -   “Shape Analysis”, Digital Image Processing, Pratt, Wiley, New York,     1991. -   “The QBIC Project”, IBM QBIC Almaden web site, home page (pp. 1–2). -   “Virage—Visual Information Retrieval”, Virage Incorporated, home     page. -   “Virage Products”, Virage Incorporated web site; pp. 1–2. -   “Visual Information Retrieval: A Virage Perspective Revision 3”,     Virage Incorporated web site; 1995; pp. 1–13. -   “Workshop Report: NSF—ARPA Workshop on Visual Information Management     Systems”, Virage Incorporated web. site; pp. 1–15. -   A. D. Bimbo, et al, “3-D Visual Query Language for Image Databases”,     Journal Of Visual Languages & Computing, 1992, pp. 257–271. -   A. E. Cawkell, “Current Activities in Image Processing Part III:     Indexing Image Collections”, CRITique, vol. 4, No. 8. May 1992, pp.     1–11, ALSIB, London. -   A. Pizano et al, “Communicating with Pictorial Databases”,     Human-Machine Interactive Systems, pp. 61–87, Computer Science Dept,     UCLA, 1991. -   A. Yamamoto et al, “Extraction of Object Features from Image and its     Application to Image Retrieval”, IEEE 9th International Conference     On Pattern Recognition, 1988, 988–991. -   A. Yamamoto et al, “Image Retrieval System Based on Object     Features”, IEEE Publication No. CH2518-9/87/0000-0132, 1987, pp.     132–134. -   A. Yamamoto et al., “Extraction of Object Features and Its     Application to Image Retrieval”, Trans. of IEICE, vol. E72, No. 6,     771–781 (June 1989). -   A. Yamamoto et al., “Extraction of Object Features from Image and     Its Application to Image Retrieval”, Proc. 9th Annual Conference on     Pattern Recognition, vol. 11, pp. 988–991 (November 1988). -   A. Soffer and H. Samet. Retrieveal by content in symbolic-image     databases. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     pages 144–155. IS&T/SPIE, 1996. -   Abadi, M., et al, “Authentication and Delegation with Smart-cards”,     Oct. 22, 1990, revised Jul. 30, 1992 Report 67, Systems Research     Center, Digital Equipment Corp., Palo Alto, Calif. -   Advertisement for “TV Decision,” CableVision, Aug. 4, 1986. -   American National Standard, “Financial Institution Retail Message     Authentication”, ANSI X9.19 1986. -   American National Standard, “Interchange Message Specification for     Debit and Credit Card Message Exchange Among Financial     Institutions”, ANSI X9.2-1988. -   Antonofs, M., “Stay Tuned for Smart TV,” Popular Science, November     1990, pp. 62–65. -   Arman et al., “Feature Management for Large Video Databases”, 1993.     (Abstract Only). ASIAN TECHNOLOGY INFORMATION PROGRAM (ATIP) REPORT:     ATIP95.65: Human Computer Interface International, July 1995     Yokohama. -   Barber et al. “Ultimedia Manager: Query by Image Content and it's     Applications” IEE, 1994, pp. 424–429, January 1994. -   Barros, et al. “Indexing Multispectral Images for Content-Based     Retrieval”, Proc. 23rd AIPR Workshop on Image and Information     Retrieval, Proc. 23rd Workshop, Washington, D.C., October 1994, pp.     25–36. -   Belkin, N. J., Croft, W. B., “Information Filtering And Information     Retrieval: Two Sides of the Same Coin?”, Communications of the ACM,     December 1992, vol. 35, No. 12, pp. 29–38. -   Benoit Mandelbrot: “Fractal Geometry of Nature”, W H Freeman and     Co., New York, 1983 (orig ed 1977). -   Benoit Mandelbrot: “Fractals—Form, Chance and Dimensions”, W H     Freeman and Co., San Francisco, 1977. -   Bimbo et al., “Sequence Retrieval by Contents through Spatio     Temporal Indexing”, IEEE on CD-ROM, pp. 88–92, Aug. 24, 1993. -   Bolot, J.; Turletti, T. & Wakeman, I.; “Scalable Feedback Control     for Multicast Video Distribution In the Internet”, Computer     Communication Review, vol. 24, No. 4 Oct. 1994, -   Proceedings of SIGCOMM 94, pp. 58–67. -   Bos et al., “SmartCash: a Practical Electronic Payment System”, pp.     1–8; August 1990. -   Branko Pecar: “Business Forecasting for Management”, McGraw-Hill     Book Co., London, 1994. -   Brian H Kaye: “A Random Walk Through Fractal Dimensions”, VCH     Verlagsgesellschaft, Weinheim, 1989. -   Brugliera, Vito, “Digital On-Screen Display—A New Technology for the     Consumer Interface”, Symposium Record Cable Sessions. Jun. 11, 1993,     pp. 571–586. -   Burk et al, “Value Exchange Systems Enabling Security and     Unobservability”, Computers & Security, 9 1990, pp. 715–721. -   C. Chang et al, “Retrieval of Similar Pictures on Pictorial     Databases”, Pattern Recognition, vol. 24, No. 7, 1991, pp. 675–680. -   C. Chang, “Retrieving the Most Similar Symbolic Pictures from     Pictorial Databases”, Information Processing & Management, vol. 28,     No. 5, 1992. -   C. Faloutsos et al, “Efficient and Effective Querying by Image     Content”, Journal of Intelligent Information Systems: Integrating     Artificial Intelligence and Database Technologies, vol. 3–4, No. 3,     July 1994, pp. 231–262. -   C. Goble et al, “The Manchester Multimedia Information System”,     Proceedings of IEEE Conference, Eurographics Workshop, April, 1991,     pp. 244–268. -   C. C. Chang and S. Y. Lee. Retrieval of similar pictures on     pictorial databases. Pattern Recog., 24(7), 1991. -   Case Study: The CIRRUS Banking Network, Comm. ACM 8, 28 pp.     7970–8078, August 1985. -   Chalmers, M., Chitson, P., “Bead: Explorations In Information     Visualization”, 15th Ann. Int'l SIGIR 92/Denmark-June 1992, pp.     330–337. -   Chang et al., “Intelligent Database Retrieval by Visual Reasoning”,     PROC Fourteenth Annual International Computer Software and     Application Conference, 31 Oct. –1 Nov. 1990, pp. 459–464. -   Chang, Yuh-Lin, Zeng, Wenjun, Kamel, Ibrahim, Alonso, Rafael,     “Integrated Image and Speech Analysis for Content-Based Video     Indexing”. -   Chaum et al, “Untraceable Electronic Cash”, Advances in Cryptology,     1988, pp. 319–327. -   Chaum et al; “Achieving Electronic Privacy”, Scientific American,     pp. 319–327; 1988. -   Chaum, D. “Security without Identification: Card Computers to Make     Big Brother Obsolete”, Communications of the ACM, 28(10), October     1985, pp. 1030–1044. -   Chaum, D. “Untraceable Electronic Mail, Return Addresses, and     Digital Pseudonyms”, Communications of the ACM, vol. 24, No. 2,     February, 1981. -   Chaum, D., “Achieving Electronic Privacy”, Scientific American,     August 1992, pp. 96–101. -   Chaum, D. L. et al.; “Implementing Capability-Based Protection Using     Encryption”; Electronics Research Laboratory, College of     Engineering, University of California, Berkeley, Calif.; Jul. 17,     1978. -   Cliff Pickover, Spiral Symmetry (World Scientific). -   Cliff Pickover, Chaos in Wonderland: Visual Adventures in a Fractal     World (St. Martin's Press). -   Cliff Pickover, Computers and the Imagination (St. Martin's Press)     Cliff Pickover, Mazes for the Mind: Computers and the Unexpected     (St. Martin's Press). -   Cliff Pickover, Computers, Pattern, Chaos, and Beauty (St. Martin's     Press). -   Cliff Pickover, Frontiers of Scientific Visualization (Wiley). -   Cliff Pickover, Visions of the Future: Art, Technology, and     Computing in the 21st Century (St. Martin's Press). -   Cohen, Danny; “Computerized Commerce”; ISI Reprint Series     ISI/RS-89/243; October, 1989; Reprinted from Information Processing     89, Proceedings of the IFIP World Computer Congress, held Aug.     28-Sep. 1, 1989. -   Cohen, Danny; “Electronic Commerce”; University of Southern     California, Information Sciences Institute, Research Report     ISI/RR-89-244; October, 1989. -   Common European Newsletter, Multimedia Content manipulation and     Management, http://ww.esat.kuleuven.ac.be/˜konijin/ . . . . -   CompuServe Information Service Users Guide, CompuServe     International, 1986, pp. 109–114. -   Computer Shopper, November 1994, “Internet for Profit”, pp. 180–182,     187, 190–192, 522–528, 532, 534. -   Computer, Vol. 28(9), September 1995. -   Compuvid Sales Manual (date unknown). -   Corporate Overview, Virage Incorporated web site; pp. 1–4. -   Cox, Ingemar J., et al., “PicHunter: Bayesian Relevance Feedback for     Image Retrieval,” Proc. of the ICPR '96, IEEE, pp. 361–369. -   Cutting, D. R.; Karger, D. R.; Pedersen, J. O. & Tukey, J. W.     “Scatter/Gather: A Cluster-based Approach to Browsing Large Document     Collections”, 15 Ann. Int'l SIGIR '92, ACM, 1992, pp. 318–329. -   D K Arrowsmith & C M Place: “An Introduction to Dynamical Systems”,     Cambridge University Press, Cambridge, 1990. -   Damashek, M., Gauging Similarity via N-Grams: Language-Independent     Sorting, Categorization, and Retrieval of Text, pp. 1–11, Jan. 24,     1995. -   Data Partner 1.0 Simplifies DB Query Routines, PC Week, Sep. 14,     1992, pp. 55 & 58. -   David E Rumelhart & James L McClelland: “Parallel Distributed     Processing”, Vol 1., The MIT Press, Cambridge, Mass., 1986. -   Deering, S.; Estrin, D.; Farinacci, D.; Jacobson, V.; Liu, C.; Wei.     L; “An Architecture for Wide-Area Multicast Routing”, Computer     Communication Review, vol. 24, No. 4, October 1994, Proceedings of     SIGCOMM 94, pp. 126–135. -   Donal Daly: “Expert Systems Introduced”, Chartwell-Bratt, Lund.     1988. -   Dukach, Seymon; Prototype Implementation of the SNPP Protocol;     allspic.lcs.mit.edu; 1992. -   E. Binaghi et al, “Indexing and Fuzzy Logic Based Retrieval of Color     Images”, Visual Database Systems, II, 1992, pp. 79–92. -   E. Binaghi et al., “A Knowledge-Based Environment for Assessment of     Color Similarity”, Proc. 2nd Annual Conference on Topics for A1, pp.     268–285 (1990). -   E. Lee, “Similarity Retrieval Techniques”, Pictorial Information     Systems, Springer Verlag, 1980 pp. 128–176. -   E. G. M. Petrakis and C. Faloutsos. Similarity searching in large     image databases. Technical Report 3388, Department of Computer     Science. University of Maryland, 1995. -   Edward Reitman: “Exploring the Geometry of Nature”, Windcrest Books,     Blue Ridge Summit, 1989. -   Even et al; “Electronic Wallet”; pp. 383–386;1983. -   F. J. Varela and P. Bourgine (eds.): Proceedings of the first     European Conference on Artificial Life. Cambridge, Mass.: MIT Press.     (1991). -   Fassihi, Theresa & Bishop, Nancy, “Cable Guide Courting National     Advertisers,” Adweek, Aug. 8, 1988. -   Flickner, et al. “Query by Image and Video Content, the QBIC     System”. IEEE Computer 28(9): 23–32, 1995. -   Foltz, P. W., Dumais, S. T., “Personalized Information Delivery: An     Analysis Of Information Filtering Methods”, Communications of the     ACM, December 1992, vol. 35, No. 12, pp. 51–60. -   Frank Pettit: “Fourier Transforms in Action”, Chartwell-Bratt, Lund.     1985. -   G F Page, J B Gomm & D Williams: “Application of Neural Networks to     Modelling and Control”, Chapman & Hall, London, 1993. -   G. Mannes, “Smart Screens”, Video Magazine, December 1993) (2     Pages). -   G. Tortora et al, “Pyramidal Algorithms”, Computer Vision, Graphics     and Images Processing, 1990, pp. 26–56. -   Gautama, S., D'Haeyer, J. P. F., “Context Driven Matching in     Structural Pattern Recognition”. -   Gautama, S., Haeyer, J. D., “Learning Relational Models of Shape: A     Study of the Hypergraph Formalism”. -   Gene F Franklin, J David Powell & Abbas Emami-Naeini: “Feedback     Control of Dynamic Systems”, Addison-Wesley Publishing Co. Reading,     1994. -   George E P Box & Gwilym M Jenkins: “Time Series Analysis:     Forecasting and Control”, Holden Day, San Francisco, 1976. -   Gifford, D., “Notes on Community Information Systems”, MIT LCS     TM-419, December 1989. -   Gifford, David K.; “Cryptographic Sealing for Information Secrecy     and Authentication”; Stanford University and Xerox Palo Alto     Research Center; Communication of the ACM; vol. 25, No. 4; April,     1982. -   Gifford, David K.; “Digital Active Advertising”; U.S. patent     application Ser. No. 08/168,519; filed Dec. 16, 1993. -   Gligor, Virgil D. et al.; “Object Migration and Authentication”;     IEEE Transactions on Software Engineering; vol. SE-5, No. 6;     November, 1979. -   Gong et al. “An Image Database System with Content Capturing and     Fast Image Indexing Abilities” IEEE, 1994, pp. 121–130, May 1994. -   Gregory L Baker & Jerry P Gollub: “Chaotic Dynamics: An     Introduction”, Cambridge University Press, Cambridge, 1990. -   Gupta, Amamath; Weymount, Terry & Jain, Ramesh, “Semantic Queries     With Pictures: The VIMSYS Model”, Proceedings of the 17th     International Conference on Very Large Data Bases, pp. 69–79,     Barcelona, September, 1991. -   H. Tamura et al, “Image Database Systems: A Survey”, Pattern     Recognition, vol. 17, No. 1, 1984, pp. 29–34. -   H. Tamura, et al., “Textural Features Corresponding to Visual     Perception,” IEEE Transactions on System, Man, and Cyb., vol. SMC-8,     No. 6, pp. 460–473 (1978). -   H. Samet. The quadtree and related hierarchical data structures. ACM     Computing Surveys, 16(2):187–260, 1984. -   Hans Lauwerier: “Fractals—Images of Chaos”, Penguin Books, London,     1991. -   Harty et al., “Case Study: The VISA Transaction Processing System,”     1988. -   Heinz-Otto Peitgen & Deitmar Saupe: “The Science of Fractal Images”,     Springer-Verlag, New York, 1988. -   Heinz-Otto Peitgen, Hartmut Jurgens & Deitmar Saupe: “Fractals for     the Classroorn”, Springer-Verlag, 1992. -   Hirata, et al. “Query by Visual Example, Content Based Image     Retrieval” Advance in Database Technology-EDBT '92, Springer-Verlag,     Berlin 1992, pp. 56–71. -   Hirzalla et al., “A Multimedia Query User Interface”, IEEE on     CD-ROM, pp. 590–593, Sep. 5, 1995. -   Hooge, Charles, “Fuzzy logic Extends Pattern Recognition Beyond     Neural Networks”, Vision Systems Design, January 1998, pp. 32–37. -   Hou et al., “Medical Image Retrieval by Spatial Features”, IEEE on     CD-ROM, pp. 1364–1369, Oct. 18, 1992. -   Iino et al., “An Object-Oriented Model for Spatio-Temporal     Synchronization of Multimedia Information”, May, 1994. -   Information Network Institute, Carnegie Mellon University, Internet     Billing Server, -   Prototype Scope Document, Oct. 14, 1993. -   Ingemar J. Cox et al., “Target Testing and the Pic Hunter Bayesian     Multimedia Retrieval System,” Proc. of the 3d Forum on Research and     Technology Advances in Digital Libraries, ADL '96, IEEE, pp. 66–75. -   Intel Corporation, iPower Technology, Marketing Brochure, date     unknown. -   Intuit Corp. Quicken User's Guide, “Paying Bills Electronically”,     pp. 171–192; undated. -   ISO/IEC JTC1/SC29/WG11 N1735, MPEG97, July 1997—Stockholm, “MPEG-7     Applications Document”. -   ISO/IEC JTC1/SC29/WG11 N2460, MPEG98, October 1998 “MPEG-7 Context     and Objectives (v.10—Atlantic City)”; ISO/IEC JTC1/SC29/WG11 N1920,     MPEG97, October 1997 “MPEG-7 Context and Objectives (v.5—Fribourg)”;     ISO/IEC JTC1/SC29/WG11 N1733, MPEG97, July 1997, “MPEG-7 Context and     Objectives (v.4—Stockholm)”. -   ISO/IEC JTC1/SC29/WG11 N2461, MPEG98, October 1998—Atlantic City,     “MPEG-7 Requirements”. -   ISO/IEC JTC1/SC29/WG11 N2462, MPEG98, October 1998—Atlantic City,     “MPEG-7 Applications”. -   ISO/IEC JTC1/SC29/WG11 N2467, MPEG98, October 1998—Atlantic City,     “MPEG-7 Content Set”. -   Itzhak Wilf, “Computer, Retrieve For Me the Video Clip of the     Winning Goal”, Advanced Imaging, August 1998, pp. 53–55. -   Ivar Ekeland: “Mathematics and the Unexpected”, The University of     Chicago Press, Chicago, 1988. -   Kenneth Falconer: “Fractal Geometry”, John Wiley & Sons, Chichester,     1990. -   Ivars Peterson: “The Mathematical Tourist”, W H Freeman, New York,     1988. -   Iyengar et al., “Codes Designs for Image Browsing”, 1994. -   J W Bruce & P J Giblin: “Curves and Singularities”, Cambridge     University Press, Cambridge, 1992. -   J. Hasegawa et al, “Intelligent Retrieval of Chest X-Ray Image     Database Using Sketches”, System And Computers In Japan, 1989, pp.     29–42. -   J. M. Chassery, et al., “An Interactive Segmentation Method Based on     Contextual Color and Shape Criterion”, IEEE Transactions on Pattern     Analysis and Machine Intelligence, vol. PAMI-6, No. 6, (November     1984). -   J. Wachman, “A Video Browser that Learns by Example”, Masters     Thesis, Massachusetts Institute of Technology; 1996; also appears as     MIT Media Laboratory Technical Report No. 383. -   J. Hafner, H. S. Sawhney, W. Equitz, M. Flickner, and W. Niblack.     Efficient color histogram indexing for quadratic form distance     functions. IEEE Trans. Pattern Anal. Machine Intell., July 1995. -   J. R. Bach, C. Fuller, A. Gupta, A. Hampapur, B. Horowitz, R.     Humphrey, R. C. Jain, and C. Shu. Virage image search engine: an     open framework for image management. In Symposium on Electronic     Imaging: Science and Technology—Storage & Retrieval for Image and     Video Databases IV, pages 76–87. IS&T/SPIE, 1996. -   J. R. Smith and S.-F. Chang. Querying by color regions using the     VisualSEEk content-based visual query system. In M. T. Maybury,     editor, Intelligent Multimedia Information Retrieval. IJCAI, 1996. -   J. R. Smith and S.-F. Chang. Tools and techniques for color image     retrieval. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     volume 2670, San Jose, Calif., February 1996. IS&T/SPIE. -   Jacobs, Charles E., Finkelstein. Adam, Salesin, David H., “Fast     Multiresolution Image Querying”. -   James Gleick: “Chaos—Making a New Science”, Heinemann, London, 1988. -   Jane Hunter, “The Application of Metadata Standards to Video     Indexing”     http://www.dtsc.edu.au/RDU/staff/jane-hunter/EuroDL/final.html     (<Dec. 24, 1998). -   Jim Binkley & Leslie Young, Rama: An Architecture for Internet     Information Filtering, Journal of Intelligent Information Systems:     Integrating Artificial Intelligence and Database Technologies, vol.     5, No. 2, September 1995, pp. 81–99. -   Jonathan Berry, “A Potent New Tool for Selling Database Marketing”,     Business Week, Sep. 5, 1994, pp. 34–40. -   Joseph L McCauley: “Chaos, Dymanics, and Fractals”, Cambridge     University Press, Cambridge, 1993. -   JPL New Technology Report NPO-20213, Nasa Tech Brief Vol. 22, No. 4,     Item #156 (April 1998). -   Judith H. Irven et al., “Multi-Media Information Services: A     Laboratory Study”, IEEE Communications Magazine, vol. 26, No. 6,     June, 1988, pp. 24–44. -   K V Mardia, J T Kent & J M Bibby: “Multivariate Analysis”, Academic     Press, London, 1979. -   K. Hirata et al, “Query by Visual Example Content Based Image     Retrieval”, Advances In Database Technology, March, 1992, pp. 57–71. -   K. Wakimoto et al, “An Intelligent User Interface to an Image     Database using a Figure interpretation Method”, IEEE Publication No.     CH2898-5/90/0000/0516, 1990, pp. 516–520. -   K. Woolsey, “Multimedia Scouting”, IEEE Computer Graphics And     Applications, July 1991 pp. 26–38. -   Kelly et al. “Efficiency Issues Related to Probability Density     Function Comparison”, -   SPIE vol. 2670, pp. 42–49 January 1996. -   Kelly, P. M., et al. “Candid Comparison Algorithm for Navigating     Digital Image Databases”, Proceedings 7th International Working     Conference on Scientific and Statistical Database Management, pp.     252–258, 1994. -   Krajewski, M. et al, “Applicability of Smart Cards to Network User     Authentication”, -   Computing Systems, vol. 7, No. 1, 1994. -   Krajewski, M., “Concept for a Smart Card Kerberos”. 15th National     Computer Security Conference, October 1992. -   Krajewski, M., “Smart Card Augmentation of Kerberos, Privacy and     Security Research Group Workshop on Network and Distributed System     Security”, February 1993. -   Lampson, Butler; Abadi, Martin; Burrows, Michael; and Wobber,     Edward; “Authentication in Distributed Systems: Theory and     Practice”: ACM Transactions on Computer Systems; vol. 10, No. 4;     November, 1992; pp. 265–310. -   Landis, Sean, “Content-Based Image Retrieval Systems for Interior     Design”,     http://www.tc.cornell.edu/Visuatization/Education/cs718/fall1995/landis/index.html. -   Langton C G (ed): Artificial Life; Proceedings of the first     international conference on Artificial life, Redwood City:     Addison-Wessley (1989). -   Lee et al., “Video Indexing—An Approach based on Moving Object and     Track”, Proceedings of Storage and Retrieval for Image and Video     Databases, pp. 25–36. February 1993. -   Lee, Denis, et al., “Query by Image Content Using Multiple Objects     and Multiple Features: User Interface Issues,” 1994 Int'l Conf. on     Image Processing, IEEE, pp. 76–80. -   Lennart Ljung & Torsten Soderstrom: “Theory and Practice of     Recursive Identification”, The MIT Press, Cambridge, Mass., 1983. -   Lennart Ljung: “System Identification; Theory for the User”,     Prentice-Hall Englewood Cliffs, N.J., 1987. -   Loeb, S., “Architecting Personalized Delivery of Multimedia     Information”, Communications of the ACM, December 1992, vol. 35, No.     12, pp. 39–50. -   M V Berry, I C Persival & N O Weiss: “Dynamical Chaos”, The Royal     Society, London, 1987, Proceedings of a Royal Society Discussion     Meeting held on 4 & 5 Feb. 1987. -   M. Bender, “EFTS: Electronic Funds Transfer Systems”, Kennikat     Press, Port Washington, N.Y., pp. 43–46 1975. -   M. H. O'Docherty et al, “Multimedia Information System—The     Management and Semantic Retrieval of all Electronic Data Types”, The     Computer Journal, vol. 34, No. 3, 1991. -   M. Ioka, “A Method of Defining the Similarity of Images on the Basis     of Color Information”, Bulletin Of The National Museum Of Ethnology     Special Issue, pp. 229–244, No. 17, November 1992. -   M. Kurokawa, “An Approach to Retrieving Images by Using their     Pictorial Features”, IBM Research, Japan, September 1989. -   M. Swain et al, “Color Indexing”, International Journal Of Computer     Vision, 1991, pp. 12–32. -   M. Stricker and A. Dimai. Color indexing with weak spatial     constraints. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     pages 29–41. IS&T/SPIE, 1996. -   M. Stricker and M. Orengo. Similarity of color images. In Storage     and Retrieval for Image and Video Databases III, volume SPIE Vol.     2420, February 1995. -   Mackay et al., “Virtual Video Editing in Interactive Multimedia     Applications”, 1989. -   Manners, George, “Smart Screens; Development of Personal Navigation     Systems for TV Viewers,” Video Magazine, December 1993. -   Martin Casdagli & Stephen Eubank: “Nonlinear Modelling and     Forecasting”, Addison-Wesley Publishing Co., Redwood City, 1992. -   Martinez et al. “Imagenet: A Global Distribution Database for Color     Image Storage and Retrieval in Medical Imaging Systems” IEEE, 1992,     710–719, May 1992. -   Marvin A. Sirbu; Internet Billing Service Design And Prototype     Implementation; pp. 1–19; An Internet Billing Server. -   Masahiro Morita & Yoichi Shinoda, Information Filtering Based on     User Behavior Analysis and Best Match Text Retrieval, Proceedings of     the Seventeenth Annual International ACM-SIGIR Conference on     Research and Development in Information Retrieval, Dublin, Jul. 3–6,     1994, Pages Title Page (272)-281. -   Medvinsy et al, “NetCash: A Design for Practical Electronic Currency     on the Internet”, Proc. 1st ACM Conf. on Comp. and Comm. Security,     November 1993. -   Medvinsy et al., “Electronic Currency for the Internet”, Electronic     Markets, pp. 30–31, September 1993. -   Meyer, J. A., Roitblat, H. L., Wilson, W. (eds.): From Animals to     Animats. Proceedings of the Second International Conference on     Simulation of Adaptive Behaviour. Cambridge, Mass.: MIT Press.     (1991). -   Middleton, G. V. ed., 1991, Nonlinear Dynamics, Chaos and Fractals,     with Applications to Geological Systems. Geol. Assoc. Canada Short     Course Notes Vol. 9 (available from the GAC at Memorial University     of Newfoundland, St. John's NF AlB 3×5). -   Mills, “Media Composition for Casual Users”, 1992. -   Minneman et al., “Where Were We: making and using near-synchronous,     pre-narrative video”, Multimedia '93, pp. 1–11. December 1993. -   N. Hutheesing, “Interactivity for the passive”, Forbes magazine Dec.     6, 1993 (@ Forbes Inc. 1993) (2 pages). -   N. S. Chang et al., “Query-by-Pictorial Example”, IEEE Transactions     on Software Engineering, vol. SE-6, No. 6, pp. 519–524 (November     1980). -   N. S. Chang, et al., “Picture Query Languages for Pictorial     Data-Base Systems”, Computer vol. 14, No. 11, pp. 23–33 (November     1981). -   Nagasaka et al., “Automatic Video Indexing and Full-Video Search for     Object Appearances”, Visual Database Systems, (Knuth et al., eds.),     pp. 113–126. January 1992. -   National Westminster Bank Group Brochure; pp. 1–29; undated. -   Needham, Roger M. and Schroeder, Michael D.; “Using Encryption for     Authentication in Large Networks of Computers”; Communications of     the ACM; vol. 21, No. 12; December, 1978; pp. 993–999. -   Needham, Roger M.; “Adding Capability Access to Conventional File     Servers”; Xerox Palo Alto Research Center; Palo Alto, Calif. -   Newman, B. C., “Proxy-Based Authorization and Accounting for     Distributed Systems”, Proc. 13th Int. Conf. on Dist. Comp. Sys., May     1993. -   Niblack, W. et al., “The QBIC Project: Querying Images by Content     Using Color, Texture, and Shape”, IBM Computer Science Research     Report, pp. 1–20 (Feb. 1, 1993). -   Nussbaumer et al., “Multimedia Delivery on Demand: Capacity Analysis     and Implications”, Proc 19th Conference on Local Computer Networks,     2–5 October 1994, pp. 380–386. -   O. Guenther and A. Buchmann. Research issues in spatial databases.     In ACM SIGMOD Record, volume 19, December 1990. -   Okamoto et al. “Universal Electronic Cash”, pp. 324–337; 1991. -   Ono, Atsushi, et al., “A Flexible Content-Based Image Retrieval     System with Combined Scene Description Keyword,” Proc. of Multimedia     '96, IEEE, pp. 201–208. -   Otis Port, “Wonder Chips-How They'll Make Computing Power Ultrafast     and Ultracheap”, Business Week, Jul. 4, 1994, pp. 86–92. -   P G Drazin: “Nonlinear System”, Cambridge University Press,     Cambridge, 1992. -   P. Stanchev et at, “An Approach to Image Indexing of Documents”.     Visual Database Systems, 11, 1992, pp. 63–77. -   Peter J Diggle: “Time Series: A Biostatistical Introduction”,     Clarendon Press, Oxford, -   1990. -   Peters:“Chaos and Order in the Capital Markets”, Wiley, 1991     Gershenfeld & Weigend: “The Future of Time Series”, Addison-Wesley,     1993. -   Pfitzmann et al; “How to Break and Repair a Provably Secure     Untraceable Payment System”; pp. 338–350; 1991. -   Phillips, “MediaView: a general multimedia digital publication     system”, Comm. of the ACM, v. 34, n. 7, pp. 75–83. July 1991. -   Predrag Cvitanovic: “Universality in Chaos”, Adam Hilger, Bristol,     1989. -   R. Mehrotra et al, “Shape Matching Utilizing Indexed Hypotheses     Generation and Testing”, IEEE Transactions On Robotics, vol. 5, No.     1, February 1989, pp. 70–77. -   R. Price, et al., “Applying Relevance Feedback to a Photo Archival     System”, Journal of Information Science 18, pp. 203–215 (1992). -   R. W. Picard et al, “finding Similar Patterns in Large Image     Databases”, IEEE ICASSP, Minneapolis, Minn., vol. V, pp. 161–164,     April 1993; also appears in MIT Media Laboratory Technical Report     No. 205. -   Rangan et al., “A Window-based Editor for Digital Video and Audio”,     January 1992. -   Richards et al., “The Interactive Island”, IEE Revies, Jul./August     1991 pp. 259–263. -   Rivest, R.; “The MD5 Message-Digest Algorithm”; MIT Laboratory for     Computer Science and RSA Data Security, Inc.; April, 1992. -   Rivest, R. L. et al., “A Method for Obtaining Digital Signatures and     Public-Key Cryptosystems,” Laboratory for Computer Science,     Massachusetts Institute of Technology, Cambridge, Mass. -   Rivest, R. L.; Shamir, A. & Adleman, L.; “A Method for Obtaining     Digital Signatures and Public-Key Cryptosystems”, Communications of     the ACM, February 1978, vol. 21, No. 2, pp. 120–126. -   Robert Brown: “Statistical Forecasting for Inventory Control”,     McGraw-Hill Book Co., New York, 1958. -   Robinson, G., and Loveless, W., “Touch-Tone’ Teletext—A Combined     Teletext-Viewdata System,” IEEE Transactions on Consumer     Electronics, vol. CE-25, No. 3, July 1979, pp. 298–303. -   Roizen, Joseph, “Teletext in the USA,” SMPTE Journal, July 1981, pp.     602–610. -   Rose, D. E.; Mander, R.; Oren, T., Ponceleon, D. B.; Salomon, G. &     Wong, Y. Y. “Content Awareness in a File System Interface     Implementing the Pile Metaphor for Organizing Information”, 16 Ann.     Int'l SIGIR '93, ACM, pp. 260–269. -   Ross Anderson, “Why Cryptosystems Fail”, Proc. 1st Conf. Computer     and Comm. Security, pp. 215–227, November 1993. -   Ross J. Anderson, “UEPS—A Second Generation Electronic Wallet”,     Proc. of the Second European Symposium on Research in Computer     Security (ESORICS). Touluse, France, pp. 411–418, Touluse, France. -   Rui, Yong, Huang, Thomas S., Chang, Shih-Fu, “Image Retrieval: Past     Present and Future”. -   Rui, Yong, Huang, Thomas S., Mehotra, Sharad, “Browsing and     retrieving Video Content in a Unified Framework”. -   Rui, Yong, Huang, Thomas S., Ortega, Michael, Mehotra, Sharad,     “Relevance Feedback: -   A Power Tool for Interactive Content-Based Image Retrieval”. -   S. Chang et al, “An Intelligent Image Database System”, IEEE     Transactions On Software Engineering, vol. 14, No. 5, May 1988, pp.     681–688. -   S. Chang et al, “Iconic Indexing by 2-D Strings”, IEEE Transactions     On Pattern Analysis And Machine Intelligence, vol. PAMI-9, No. 3,     May 1987. -   S. Chang et al, “Iconic Indexing by 2-D Strings”, IEEE Transactions     On Pattern Analysis And Machine Intelligence, vol. 9, No. 3, May     1987, pp. 413–427. -   S. Charles et al., “Using Depictive Queries to Search Pictorial     Databases”, Human Computer Interaction, 1990, pp. 493–498. -   S. Lee et al, “2D C-string: A New Spatial Knowledge Representation     for Image Database Systems”, Pattern Recognition, vol. 23, 1990, pp.     1077–1087. -   S. Lee et al, “Similarity Retrieval of Iconic Image Database”,     Pattern Recognition, vol. 22, No. 6 1989, pp. 675–682. -   S. Lee et al, “Spatial Reasoning and Similarity Retrieval of Images     Using 2D C-string Knowledge Representation”, Pattern Recognition,     1992, pp. 305–318. -   S. Negahdaripour et al “Challenges in Computer Vision: Future     Research Direction”, IEEE Transactions On Systems, Man And     Cybernetics, pp. 189–199, 1992, at Conference on Computer Vision and     Pattern Recognition. -   S. Tanaka et al, “Retrieval Method for an Image Database based on     Topological Structure”, SPIE, vol. 1153, 1989, pp. 318–327. -   S.-F. Chang. Compressed-domain techniques for image/video indexing     and manipulation. In Proceedings, I.E.E.E. International Conference     on Image Processing, Washington, D.C., October 1995, invited paper     to the special session on Digital Library and Video on Demand. -   S.-K. Chang, Q. Y. Shi, and C. Y. Yan. Iconic indexing by 2-D     strings. IEEE Trans. Pattern Anal. Machine Intell., 9(3):413–428,     May 1987. -   S.-K. Chang. Principles of Pictorial Information Systems Design.     Prentice Hall, 1989. -   Salton, G., “Developments in Automatic Text Retrieval”, Science,     vol. 253, pp. 974–980, Aug. 30, 1991. -   Schamuller-Bichl, I., “IC-Cards in High-Security Applications”, in     Selected Papers from the Smart Card 2000 Conference, Springer     Verlag, 1991, pp. 177–199. -   Semyon Dukach, “SNPP: A Simple Network Payment Protocol”, MIT     Laboratory for Computer Science, Cambridge, Mass., 1993. -   Shann et al. “Detection of Circular Arcs for Content-Based Retrieval     from an Image Database” IEE Proc.-Vis. Image Signal Process, vol.     141, No. 1, February 1994, pp. 49–55. -   Sheldon G Lloyd & Gerald D Anderson: “Industrial Process Control”.     Fisher Controls Co., Marshalltown, 1971. -   Sheth et al., “Evolving Agents for Personalized Information     Filtering”. 1–5 March 1993, pp. 345–352. -   Sheth, B. & Maes, P. “Evolving Agents For Personalized Information     Filtering”, Proc. 9th IEEE Conference, 1993 pp. 345–352. -   Sincoskie, W. D. & Cotton C. J. “Extended Bridge Algorithms for     Large Networks”, IEEE Network, January 1988-vol. 2, No. 1, pp.     16–24. -   Smith, J. et al., “Quad-Tree Segmentation for Texture-Based Image     Query” Proceeding ACM Multimedia 94, pp. 1–15, San Francisco, 1994. -   Smoliar, S. et al., “Content-Based Video Indexing and Retrieval”,     IEEE Multimedia, pp. 62–72 (Summer 1994). -   Society for Worldwide Interbank Financial Telecommunications S.C.,     “A.S.W.I.F.T. Overview”, undated. -   Spyros Makridakis & Steven Wheelwright: “The Handbook of     Forecasting”, John Wiley, New York, 1982. -   Steven C Chapra & Raymond P Canale: “Numerical Methods for     Engineers”, McGraw-Hill Book Co., New York, 1988. -   T. Arndt, “A Survey of Recent Research in Image Database     Management”, IEEE Publication No. TH0330-1190/0000/0092, pp. 92–97,     1990. -   T. Gevers et al, “Enigma: An Image Retrieval System”, IEEE 11th IAPR     International Conference On Pattern Recognition, 1992, pp. 697–700. -   T. Gevers et al, “Indexing of Images by Pictorial Information”,     Visual Database Systems, 11, 1992 IFIP, pp. 93–101. -   T. Kato et al, “A Cognitive Approach Interaction”, International     Conference Of Multimedia Information Systems, January, 1991, pp.     109–119. -   T. Kato et al, “Trademark: Multimedia Database with Abstracted     Representation on Knowledge Base”, Proceedings Of The Second     International Symposium On Interoperable Information Systems, pp.     245–252, November 1988. -   T. Kato et al, “Trademark: Multimedia Image Database System with     Intelligent Human Interface”, System And Computers In Japan, 1990,     pp. 33–46. -   T. Kato, “A Sketch Retrieval Method for Full Color Image     Database-Query by Visual Example”, IEEE, Publication No.     0-8186-2910-X/92, 1992, pp. 530–533. -   T. Kato, “Intelligent Visual Interaction with Image Database Systems     Toward the Multimedia Personal Interface”, Journal Of Information     Processing, vol. 14, No. 2, 1991, pp. 134–143. -   T. Minka, “An Image Database Browser that Learns from User     Interaction”, Masters Thesis, Massachusetts Institute of Technology;     1996; also appears as MIT Media Laboratory Technical Report 365. -   T.-S. Chua, S.-K. Lim, and H.-K. Pung. Content-based retrieval of     segmented images. In Proc. ACM Intern. Conf. Multimedia, October     1994. -   Tak W. Yan & Hector Garcia-Molina, SIFT —A Tool for Wide-Area     Information Dissemination, 1995 USENIX Technical Conference, New     Orleans, La., Jan. 16–20, pp. 177–186. -   Tanton, N. E., “UK Teletext—Evolution and Potential,” IEEE     Transactions on Consumer Electronics, vol. CE-25, No. 3, July 1979,     pp. 246–250. -   Tenenbaum, Jay M. and Schiffman, Allan M.; “Development of Network     Infrastructure and Services for Rapid Acquisition”; adapted from a     white paper submitted to DARPA by MCC in collaboration with EIT and     ISI. -   Training Computers To Note Images, New York Times, Apr. 15, 1992. -   Turcotte, Donald L., 1992, Fractals and Chaos in Geology and     Geophysics. Cambridge U.P. -   TV Communications Advertisement for MSI Datacasting Systems, January     1973. -   V. Gudivada et al, “A Spatial Similarity Measure for Image Database     Applications”, Technical Report 91-1, Department of Computer     Science, Jackson, Miss., 39217, 1990–1991. -   V. N. Gudivada and V. V. Raghavan. Design and evaluation of     algorithms for image retrieval by spatial similarity. ACM Trans. on     Information Systems, 13(2), April 1995. -   Vittal, J., “Active Message Processing: Message as Messengers”, pp.     175–195; 1981. -   Voydock, Victor et al.; “Security Mechanisms in High-Level Network     Protocols”; -   Computing Surveys; vol. 15, No. 2; June 1981. -   W Gellert, H Kustner, M Hellwich & H Kastner: “The VNR Concise     Encyclopedia of Mathematics”, Van Nostrand Reinhols Co., New York,     1975. -   W. Grosky et al, “A Pictorial Index Mechanism for Model-based     Matching”, Data 7 Knowledge Engineering 8, 1992, pp. 309–327. -   W. Grosky et al, “Index-based Object Recognition in Pictorial Data     Management”, Computer Vision, 1990, pp. 416–436. -   W. Niblack et al, “Find me the Pictures that Look Like This: IBM'S     Image Query Project”, Advanced Imaging, April 1993, pp. 32–35. -   W. Niblack, R. Barber, W. Equitz, M. Flickner, E. Glasman, D.     Petkovic, P. Yanker, and C. Faloutsos. The QBIC project: Querying     images by content using color, texture, and shape. In Storage and     Retrieval for Image and Video Databases, volume SPIE Vol. 1908,     February 1993. -   W. T. Freeman et al, “The Design and Use of Steerable Filters”, IEEE     Transactions on Pattern Analysis and Machine Intelligence, vol. 15,     No. 9, September 1991, pp. 891–906. -   Weber et al., “Marquee: A Tool for Real-Time Video Logging”, CHI     '94. April 1994. -   Willett, P., “Recent Trends in Hierarchic Document Clustering: A     Critical Review”, Information Processing & Management, vol. 24, No.     5, pp. 557–597, 1988 William L. Thomas, “Electronic Program Guide     Applications—The Basics of System Design”, 1994 NCTA Technical     Papers, pp. 15–20. -   X. Zhang, et al, “Design of a Relational Image Database Management     System: IMDAT”, IEEE Publication No. TH0166-9/87/0000-0310, 1987,     pp. 310–314. -   Y. Okada, et al., “An Image Storage and Retrieval System for Textile     Pattern Adaptable to Color Sensation of the Individual”, Trans.     Inst. Elec. Inf. Comm., vol. J70D, No. 12, pp. 2563–2574, December     1987 (Japanese w/English Abstract). -   Y. Yoshida et al, “Description of Weather Maps and Its Application     to Implementation of Weather Map Database”, IEEE 7th International     Conference On Pattern Recognition, 1984, pp. 730–733. -   Yan et al., “Index Structures for Information Filtering Under the     Vector Space Model”, PROC the 10th International Conference on Data     Engineering, pp. 14–18 of DRD203RW User's Manual relating to the DSS     Digital System. -   Z. Chen et al, “Computer Vision for Robust 3D Aircraft Recognition     with Fast Library Search”, Pattern Recognition, vol. 24, No. 5, pp.     375–390, 1991, printed in Great Britain. -   Zhuang, Yueting, Rui, Yong, Huang, Thomas S., Mehotra. Sharad.     “Applying Semantic Association to Support Content-Based Video     Retrieval”.

Video on Demand

Video on demand has long been sought as a means for delivering personalized media content. The practical systems raise numerous issues, including data storage formats, retrieval software, server hardware architecture, multitasking and buffering arrangements, physical communications channel, logical communications channel, receiver and decoder system, user interface, etc. In addition, typically a pay-per-view concept may be employed, with concomitant subscription, royalty collection and accounting issues. See, e.g.:

-   A. D. Gelman, et al.: A Store-And-Forward Architecture For     Video-On-Demand Service; ICC 91 Conf.; June 1991; pp. 842–846. -   Caitlin Bestler: Flexible Data Structures and Interface Rituals For     Rapid Development of OSD Applications; 93 NCTA Tech. Papers; Jun. 6,     1993; pp. 223–236. -   Consumer Digest advertisement: Xpand Your TV's Capability:     Fall/Winter 1992; p. 215. -   Daniel M. Moloney: Digital Compression in Todays Addressable     Enviroment; 1993 NCTA Technical Papers; Jun. 6, 1993; pp. 308–316. -   Great Presentations advertisement: Remote, Remote; 1987; p. 32H. -   Henrie van den Boom: An Interactive Videotex System for Two-Way CATV     Networks; AEU, Band 40; 1986; pp. 397–401. -   Hong Kong Enterprise advertisement: Two Innovative New Consumer     Products From SVI; November 1988; p. 379. -   IEEE Communications Magazine; vol. 32, No. 5, May 1994 New York,     N.Y., US, pp. 68–80, XP 000451097 Chang et al “An Open Systems     Approach to Video on Demand”. -   Proceedings of the IEEE, vol. 82, No. 4, April 1994 New York, N.Y.,     US, pp. 585–589, XP 000451419 Miller “A Scenario for the Deployment     of Interactive Multimedia Cable Television Systems in the United     States in the 1990's”. -   Reimer, “Memories in my Pocket”, Byte, pp. 251–258, February 1991. -   Sharpless, “Subscription teletext for value added services”, August     1985.     Demographically Targeted Advertising Through Electronic Media

Since the advent of commercially subsidized print media, attempts have been made to optimize the placement and compensation aspects relating to commercial messages or advertisements in media. In general, advertisers subsidize a large percentage of the cost of mass publications and communications, in return for the inclusion and possibly strategic placement of advertisements in the publication. Therefore, the cost of advertising in such media includes the cost of preparation of the advertisement, a share of the cost of publication and a profit for the content provider and other services. Since the advertiser must bear some of the cost of production and distribution of the content, in addition to the cost of advertisement placement itself, the cost may be substantial. The advertiser justifies this cost because the wide public reception of the advertisement, typically low cost per consumer “impression”, with a related stimulation of sales due to commercial awareness of the advertisers' products and services. Therefore, the advertisement is deemed particularly effective if either the audience is very large, with ad response proportionate to the size of the audience, or if it targets a particularly receptive audience, with a response rate higher than the general population.

On the other hand, the recipient of the commercial publication is generally receptive of the advertisement, even though it incurs a potential inefficiency in terms of increased data content and inefficiencies in receiving the content segment, for two reasons. First, the advertisements subsidize the publication, lowering the monetary cost to the recipient. Second, it is considered economically efficient for a recipient to review commercial information relating to prospective purchases or expenditures, rather than directly soliciting such information from the commercial source, i.e., “push” is better than “pull”. For this reason specialty publications are produced, including commercial messages appropriate for the particular content of the media or the intended recipients. In fact, in some forms of publications, most, if not all the information content is paid advertisements, with few editorial or independently produced pieces.

Mass media, on the other hand, tends not to include specialty commercial messages, because the interested population is too disperse and the resulting response rate from an advertisement too low, and further because the majority of the audience will be disinterested or even respond negatively to certain messages. Thus, mass media generally includes a majority of retail advertisements, with specialty advertisements relegated, if at all, to a classified section which is not interspersed with other content.

This is the basis for a “least common denominator” theory of marketing, that mass media must merchandise to the masses, while specialty media merchandises to selected subpopulations. As a corollary, using such types of media, it may be difficult to reach certain specialized populations who do not consistently receive a common set of publications or who receive primarily publications which are unspecialized or directed to a different specialty.

Where a recipient has limited time for reviewing media, he or she must divide his or her available time between mass media and specialty media. Alternatively, publication on demand services have arisen which select content based on a user's expressed interests. Presumably, these same content selection algorithms may be applied to commercial messages. However, these services are primarily limited distribution, and have content that is as variable as commercial messages. Likewise, mass media often has regionally variable content, such as local commercials on television or cable systems, or differing editions of print media for different regions. Methods are known for demographic targeting of commercial information to consumers; however, both the delivery methods and demographic targeting methods tend to be suboptimal.

Sometimes, however, the system breaks down, resulting in inefficiencies. These result where the audience or a substantial proportion thereof is inappropriate for the material presented, and thus realize a low response rate for an advertiser or even a negative response for the media due to the existence of particular commercial advertisers. The recipients are bombarded with inappropriate information, while the advertiser fails to realize optimal return on its advertising expenditures. In order to minimize the occurrence of these situations, services are available, including A.C. Nielsen Co. and Arbitron, Inc., which seek to determine the demographics of the audience of broadcast media.

U.S. Pat. No. 5,436,653, incorporated herein by reference, relates to a broadcast segment recognition system in which a signature representing a monitored broadcast segment is compared with broadcast segment signatures in a data base representing known broadcast segments to determine whether a match exists. Therefore, the broadcast viewing habits of a user may be efficiently and automatically monitored, without pre-encoding broadcasts or the like.

U.S. Pat. No. 5,459,306, incorporated herein by reference, relates to a method for delivering targeting information to a prospective individual user. Personal user information is gathered, as well as information on a user's use of a product, correlated and stored. Classes of information potentially relevant to future purchases are then identified, and promotions and recommendations delivered based on the information and the user information.

U.S. Pat. No. 5,483,278, incorporated herein by reference, relates to a system having a user interface which can access downloaded electronic programs and associated information records, and which can automatically correlate the program information with the preferences of the user, to create and display a personalized information database based upon the results of the correlation. Likewise, U.S. Pat. No. 5,223,914, expressly incorporated herein by reference, relates to a system and method for automatically correlating user preferences with a T.V. program information database.

U.S. Pat. No. 5,231,494, expressly incorporated herein by reference, relates to a system which selectively extracts one of a plurality of compressed television signals from a single channel based on viewer characteristics.

U.S. Pat. No. 5,410,344 relates to a system for selecting video programs based on viewers preferences, based on content codes of the programs.

U.S. Pat. No. 5,485,518, incorporated herein by reference, relates to a system for electronic media program recognition and choice, allowing, for example, parental control of the individual programs presented, without requiring a transmitted editorial code.

Videoconferencing Technologies

Videoconferencing systems are well known in the art. A number of international standards have been defined, providing various telecommunication bandwidth and communication link options. For example, H.320, H.323 and H.324 are known transport protocols over ISDN, packet switched networks and public switched telephone networks, respectively. H.324 provides a multimedia information communication and videoconferencing standard for communication over the standard “plain old telephone system” network (“POTS”), in which the video signal is compressed using DCT transforms and motion compensation for transmission over a v.80 synchronous v.34-type modem link. The video image is provided as a video window with relatively slow frame rate. This image, in turn, may be presented on a computer monitor or television system, with appropriate signal conversion. See, Andrew W. Davis, “Hi Grandma!: Is It Time for TV Set POTS Videoconferencing?”, Advanced Imaging, pp. 45–49 (March 1997); Jeff Child, “H.324 Paves Road For Mainstream Video Telephony”, Computer Design, January 1997, pp. 107–110. A newly proposed set of extensions to H.324, called H.3241M, provides compatibility with mobile or impaired telecommunications systems, and accommodates errors and distortions in transmissions, reduced or variable transmission rates and other anomalies of known available mobile telecommunications systems, such as Cellular, GSM, and PCS.

Four common standards are employed, which are necessary for videoconferencing stations to communicate with each other under common standards. The first is called h.320, and encompasses relatively high bandwidth systems, in increments of 64 kbits/sec digital communication with a synchronous communication protocol. Generally, these systems communicate with 128 kbits/sec, 256 kbits/sec or 384 kbits/sec, over a number of “bonded” ISDN B-channels. The second standard h.324, employs a standard POTS communication link with a v.80/v.34bis modem, communicating at 33.6 kbits/sec synchronous. The third standard, is the newly established H.321 standard, which provides for videoconferencing over a packet switched network, such as Ethernet, using IPX or TCP/IP. Finally, there are so-called Internet videophone systems, such as Intel Proshare. See, Andrew W. Davis, “The Video Answering Machine: Intel ProShare's Next Step”, Advanced Imaging, pp. 28–30 (March 1997).

In known standards-based videoconferencing systems, the image is generally compressed using a discrete cosine transform, which operates in the spatial frequency domain. In this domain, visually unimportant information, such as low frequencies and high frequency noise are eliminated, leaving visually important information. Further, because much of the information in a videoconference image is repeated in sequential frames, with possible movement, this redundant information is transmitted infrequently and filtered from the transmitted image stream, and described with motion vector information. This motion vector information encodes objects which are fixed or move somewhat between frames. Such known techniques include H.261, with integer pixel motion estimation, and H.263, which provides 1/2 pixel motion estimation. Other techniques for video compression are known or have been proposed, such as H.263+, and MPEG-4 encoding. Many standard videoconferencing protocols require the initial transmission of a full frame image, in order to set both transmitting and receiving stations to the same encoding state. The digital data describing this image is typically Huffman encoded for transmission. Multiple frames may be combined and coded as a unit, for example as so-called PB frames. Other techniques are also known for reducing image data transmission bandwidth for various applications, including video conferencing.

Each remote videoconference terminal has an interface system, which receives the digital data, and separates the video information (H.261, H.263), audio information (G.711, G.723, G.723.1), data protocol information (HDLC, V.14, LAPM, etc.) and control information (H.245, H.221/H.223) into discrete streams, which are processed separately. Likewise, each terminal interface system also assembles the audio information, video information, data protocols and control data for transmission. The control information consists of various types of information; the standard control protocol which addresses the data format, error correction, exception handling, and other types of control; and the multipoint control information, such as which remote videoconference terminal(s) to receive audio information from, selective audio muting, and such. Generally, the standard, low level control information is processed locally, at the codec interface system, and filtered from the remainder of the multipoint control system, with only the extracted content information made available to the other stations.

The ITU has developed a set of multipoint videoconferencing standards or recommendations, T.120–T.133, T.RES series, H.231, H.243, etc. These define control schemes for multiple party video conferences. Typically, these protocols are implemented in systems which either identically replicate the source image data stream from one source to a plurality of destinations, or completely decode and reencode the image in a different format in a “transcoder” arrangement, to accommodate incompatible conference stations. The ITU standards also allow optional data fields which may be used to communicate digital information essentially outside the videoconference scheme, and provide data conferencing capabilities, which allow videoconferencing and data conferencing to proceed simultaneously. See, ITU T.120–T.127, T.130–T.133, T.RES, T.Share and T.TUD recommendations, expressly incorporated herein by reference.

There are a number of known techniques for transmitting and displaying alphanumeric data on a television, the most common of which are teletext, used primarily in Europe, and closed caption, which is mandated in television sets larger than 13 inches by the Television Decoder Circuitry Act of 1990, and Section 305 of the Telecommunications Act of 1996, and Federal Communication Commission (FCC) regulations. The American closed caption standard is EIA 608. The later is of particular interest because many current generation televisions, especially, larger sizes, include a closed caption decoder, and thus require no external hardware or connections, separate from the hardware and cabling for supplying the video signal. See, TCC Tech Facts, Vols. 1–4, (www.wgbh.org, rev. September 1995) expressly incorporated herein by reference. The closed caption signal is distributed on Line 21 of the vertical blanking interval. The existing standard supports 480 bits/sec, with a potential increase to 9600 bits/sec in the forthcoming ATSC standard.

Known systems provide a videoconferencing system which resides in a “set top box”, i.e., a stand-alone hardware device suitable for situation on top of a television set, providing all of the necessary functionality of a videoconferencing system employing the television as the display and possibly audio speaker functions. These systems, however, do not integrate the television functions, nor provide interaction between the video and videoconferencing systems. C-Phone Inc., Wilmington N.C., provides a C-Phone Home product line which provides extensions to H.324 and/or H.320 communications in a set-top box.

Other known videophone and videoconferencing devices are disclosed, e.g., in U.S. Pat. Nos. 5,600,646; 5,565,910; 5,564,001; 5,555,443; 5,553,609; 5,548,322; 5,542,102; 5,537,472; 5,526,405; 5,509,009; 5,500,671; 5,490,208; 5,438,357; 5,404,579; 5,374,952; 5,224,151; 4,543,665; 4,491,694; 4,465,902; 4,456,925; 4,427,847; 4,414,432; 4,377,729; 4,356,509; 4,349,701; 4,338,492; 4,008,376 and 3,984,638 each of which is expressly incorporated herein by reference.

Known Web/TV devices (from Sony/Magnavox/Philips) allow use of a television to display alphanumeric data, as well as audiovisual data, but formats this data for display outside the television. In addition, embedded Web servers are also known. See, Richard A. Quinell, “Web Servers in embedded systems enhance user interaction”, EDN, Apr. 10, 1997, pp. 61–68, incorporated herein by reference. Likewise, combined analog and digital data transmission schemes are also known. See. U.S. Pat. No. 5,404,579.

A class of computing devices, representing a convergence of personal computers and entertainment devices, and which provide network access to the Internet (a publicly available network operating over TCP/IP). ITU standards for communications systems allow the selective addition of data, according to T.120–T.133, T.RES series of protocols, as well as HDLC, V.14, LAPM, to the videoconference stream, especially where excess bandwidth is available for upload or download.

A system may be provided with features enabling it to control a so-called smart house and/or to be a part of a security and/or monitoring system, with imaging capability. These functions are provided as follows. As discussed above, various data streams may be integrated with a videoconference data stream over the same physical link. Therefore, external inputs and outputs may be provided to the videophone or videoconference terminal, which maybe processed locally and/or transmitted over the telecommunications link. The local device, in this case, is provided with a continuous connection or an autodial function, to create a communications link as necessary. Therefore, heating ventilation and air conditioning control (HVAC), lighting, appliances, machinery, valves, security sensors, locks, gates, access points, etc., may all be controlled locally or remotely through interfaces of the local system, which may include logic level signals, relays, serial ports, computer networks, fiber optic interfaces, infrared beams, radio frequency signals, transmissions through power lines, standard-type computer network communications (twisted pair, coaxial cable, fiber optic cable), acoustic transmissions and other known techniques. Likewise, inputs from various devices and sensors, such as light or optical, temperature, humidity, moisture, pressure, fluid level, security devices, radio frequency, acoustic, may be received and processed locally or remotely. A video and audio signal transmission may also be combined with the data signals, allowing enhanced remote monitoring and control possibilities. This information, when transmitted through the telecommunication link, may be directed to another remote terminal, for example a monitoring service or person seeking to monitor his own home, or intercepted and processed at a central control unit or another device. Remote events may be monitored, for example, on a closed caption display mode of a television attached to a videophone.

While the preferred embodiments of the invention adhere to established standards, the present invention also encompasses communications which deviate from or extend beyond such standards, and thus may engage in proprietary communications protocols, between compatible units.

Other References

In addition, the following patents are considered relevant to the data compression and pattern recognition functions of the apparatus and interface of the present invention and are incorporated herein by reference: U.S. Pat. Nos. 3,609,684; 3,849,760:3,950,733; 3,967,241; 4,025,851; 4,044,243; 4,100,370; 4,118,730; 4,148,061; 4,213,183; 4,225,850; 4,228,421; 4,230,990; 4,245,245; 4,254,474; 4,264,924; 4,264,925; 4,305,131; 4,326,259; 4,331,974; 4,338,626; 4,390,904; 4,395,780; 4,420,769; 4,442,544; 4,449,240; 4,450,531; 4,468,704; 4,491,962; 4;499,601; 4,501,016; 4,511,918; 4,543,660; 4,546,382; 4,547,811; 4,547,899; 4,581,762; 4,593,367; 4,602,279; 4,630,308; 4,646,250; 4,656,665; 4,658,429; 4,658,370; 4,660,166; 4,677,466; 4,697,209; 4,672,683; 4,677,680; 4,682,365; 4,685,145; 4,695,975; 4,710,822; 4,710,964; 4,716,404; 4,719,591; 4,731,863; 4,734,786; 4,736,439; 4,739,398; 4,742,557; 4,747,148; 4,752,890; 4,653,109; 4,760,604; 4,764,971; 4,764,973; 4,771,467; 4,773,024; 4,773,099; 4,774,677; 4,775,935; 4,783,752; 4,783,754; 4,783,829; 4,789,933; 4,790,025; 4,799,270; 4,802,103; 4,803,103; 4,803,736; 4,805,224; 4,805,225; 4,805,255; 4,809,331; 4,809,341; 4,817,171; 4,817,176; 4,821,333; 4,823,194; 4,829,453; 4,831,659; 4,833,637; 4;837,842; 4,843,562; 4,843,631; 4,845,610; 4,864,629; 4,872,024; 4,876,731; 4,881,270; 4,884,217; 4,887,304; 4,888,814; 4,891,762; 4,893,346; 4,897,811; 4,905,162; 4,905,286; 4,905,296; 4,906,099; 4,906,940; 4,908,758; 4,914,708; 4,920,499; 4,926,491; 4,930,160; 4,931,926; 4,932,065; 4,933,872; 4,941,193; 4,944,023; 4,949,187; 4,956,870; 4,958,375; 4,958,375; 4,964,077; 4,965,725; 4,967,273; 4,972,499; 4,979,222; 4,987,604; 4,989,256; 4,989,258; 4,992,940; 4,995,078; 5,012,334; 5,014,219; 5,014,327; 5,018,218; 5,018,219; 5,019,899; 5,020,112; 5,020,113; 5,022,062; 5,027,400; 5,031,224; 5,033,101; 5,034,991; 5,038,379; 5,038,390; 5,040,134; 5,046,121; 5,046,122; 5,046,179; 5,047,867; 5,048,112; 5,050,223; 5,051,840; 5,052,043; 5,052,045; 5,052,046; 5,053,974; 5,054,093; 5,054,095; 5,054,101; 5,054,103; 5,055,658; 5,055,926; 5,056,147; 5,058,179; 5,058,180; 5,058,183; 5,058,186; 5,059,126; 5,060,276; 5,060,277; 5,060,279; 5,060,282; 5,060,285; 5,061,063; 5,063,524; 5,063,525; 5,063,603; 5,063,605; 5,063,608; 5,065,439; 5,065,440; 5,065,447; 5,067,160; 5,067,161; 5,067,162; 5,067,163; 5,067,164; 5,068,664; 5,068,723; 5,068,724; 5,068,744; 5,068,909; 5,068,911; 5,076,662; 5,099,422; 5,103,498; 5,109,431; 5,111,516; 5,119,507; 5,122,886; 5,130,792; 5,132,992; 5,133,021; 5,133,079; 5,134,719; 5,148,497; 5,148,522; 5,155,591; 5,159,474; 5,161,204; 5,168,529; 5,173,949; 5,177,796; 5,179,652; 5,202,828; 5,220,420; 5,220,648; 5,223,924; 5,231,494; 5,239,617; 5,247,347; 5,247,651; 5,259,038; 5,274,714; 5,283,641; 5,303,313; 5,305,197; 5,307,421; 5,315,670; 5,317,647; 5,317,677; 5,343,251; 5,351,078; 5,357,276; 5,381,158; 5,384,867; 5,388,198; 5,390,125; 5,390,281; 5,410,343; 5,410,643; 5,416,856; 5,418,951; 5,420,975; 5,421,008; 5,428,559; 5,428,727; 5,428,730; 5,428,774; 5,430,812; 5,434,933; 5,434,966; 5,436,653; 5,436,834; 5,440,400; 5,446,891; 5,446,919; 5,455,892; 5,459,517; 5,461,699; 5,465,308; 5,469,206; 5,477,447; 5,479,264; 5,481,294; 5,481,712; 5,483,278; 5,485,219; 5,485,518; 5,487,132; 5,488,425; 5,488,484; 5,495,292; 5,496,177; 5,497,314; 5,502,774; 5,504,518; 5,506,768; 5,510,838; 5,511,134; 5,511,153; 5,515,098; 5,515,099; 5,515,173; 5,515,453; 5,515,471; 5,517,598; 5,519,452; 5,521,841; 5,521,984; 5,522,155; 5,523,796; 5,524,065; 5,526,427; 5,535,302; 5,541,638; 5,541,662; 5,541,738; 5,543,929; 5,544,254; 5,546,475; 5,548,667; 5,550,575; 5,550,928; 5,550,965; 5,552,833; 5,553,221; 5,553,277; 5,554,983; 5,555,495; 5,557,728; 5,559,548; 5,560,011; 5,561,649; 5,561,718; 5,561,796; 5,566,274; 5,572,604; 5,574,845; 5,576,950; 5,579,471; 5,581,658; 5,586,218; 5,588,074; 5,592,560; 5,574,845; 5,579,471; 5,581,665; 5,581,800; 5,583,560; 5,586,025; 5,594,661; 5,594,911; 5,596,705; 5,600,733; 5,600,775; 5,604,542; 5,604,820; 5,604,823; 5,606,655; 5,611,020; 5,613,032; 5,614,940; 5,617,483; 5,617,565; 5,621,454; 5,621,484; 5,621,579; 5,621,903; 5,625,715; 5,625,783; 5,627,915; 5,634,849; 5,635,986; 5,642,434; 5,644,686; 5,644,735; 5,654,771; 5,655,117; 5,657,397; 5,659,653; 5,659,368; 5,659,732; 5,664,046; 5,668,897; 5,671,343; 5,671,411; 5,682,437; 5,696,964; 5,701,369; 5,710,601; 5,710,833; 5,710,834; 5,715,400; 5,717,814; 5,724,424; 5,724,472; 5,729,741; 5,734,893; 5,737,444; 5,740,274; 5,745,126; 5,745,640; 5,745,710; 5,751,286; 5,751,831; 5,754,938; 5,758,257; 5,761,655; 5,764,809; 5,767,893; 5,767,922; 5,768,421; 5,768,426; 5,768,437; 5,778,181; 5,797,001; 5,798,785; 5,799,109; 5,801,750; 5,801,753; 5,805,763; 5,809,471; 5,819,288; 5,828,809; 5,835,087; 5,850,352; 5,852,823; 5,857,181; 5,862,260; H 331; and Re. 33,316. The aforementioned patents, some of which are mentioned elsewhere in this disclosure, and which form a part of this disclosure, may be applied in known manner by those skilled in the art in order to practice various embodiments of the present invention.

The following scientific articles, some of which are discussed elsewhere herein, are understood by those skilled in the art and relate to the pattern recognition and image compression functions of the apparatus and interface of the present invention:

-   “Fractal Geometry-Understanding Chaos”, Georgia Tech Alumni     Magazine, p. 16 (Spring 1986). -   “Fractal Modelling of Biological Structures”, School of Mathematics,     Georgia Institute of Technology (date unknown). -   “Fractal Modelling of Real World Images”, Lecture Notes for     Fractals: Introduction, Basics and Perspectives, Siggraph (1987). -   “Fractals Yield High Compression”, Electronic Engineering Times,     Sep. 30, 1991, p. 39. -   “Fractals—A Geometry of Nature”, Georgia Institute of Technology     Research Horizons, p. 9 (Spring 1986). -   “Voice Recognition and Speech Processing”, Elektor Electronics,     September 1985, pp. 56–57. -   Aleksander, I., “Guide to Pattern Recognition Using Random-Access     Memories”, Computers and Digital Techniques, 2(1):29–40 (February     1979). -   Anderson, F., W. Christiansen, B. Kortegaard, “Real Time, Video     Image Centroid Tracker”, Apr. 16–20, 1990. -   Anson, L., M. Barnsley, “Graphics Compression Technology”, SunWorld,     pp. 43–52 (October 1991). -   Appriou, A., “Interet des theories de l'incertain en fusion de     donnees”, Colloque International sur le Radar Paris, 24–28 avril     1989. -   Appriou, A., “Procedure d'aide a la decision multi-informateurs.     Applications a la classification multi-capteurs de cibles”,     Symposium de l'Avionics Panel (AGARD) Turquie, 25–29 avril 1988. -   Arrow, K. J., “Social choice and individual valves”, John Wiley and     Sons Inc. (1963). -   Barnsley et al., “A Better Way to Compress Images”, Byte Magazine,     January 1988. -   Barnsley et al., “Harnessing Chaos For Images Systhesis”, Computer     Graphics, 22(4) (Aug. 1988). -   Barnsley et al., “Hidden Variable Fractal Interpolation Functions”,     School of Mathematics, Georgia Institute of Technology, Atlanta, Ga.     30332, July, 1986. -   Batchelor, B. G., “Pattern Recognition, Ideas in Practice”, Plenum     Press, London and New York, (1978). -   Batchelor, B. G., “Practical Approach to Pattern Classification”,     Plenum Press, London and New York, (1974). -   Bellman, R. E., L. A. Zadeh, “Decision making in a fuzzy     environment”, Management Science, 17(4) (December 1970). -   Bhatnagar, R. K., L. N. Kamal, “Handling uncertain information: a     review of numeric and non-numeric methods”, Uncertainty in     Artificial Intelligence, L. N. Kamal and J. F. Lemmer, Eds. (1986). -   Blair, D., R. Pollack, “La logique du choix collectif”, Pour 1 a     Science (1983). -   Burr, D. J., “A Neural Network Digit Recognizer”, Proceedings of the     1986 IEEE International Conference of Systems, Man and Cybernetics,     Atlanta, Ga., pp. 1621–1625. -   Caffery, B., “Fractal Compression Breakthrough for Multimedia     Applications”, Inside, Oct. 9, 1991. -   Carpenter, G. A., S. Grossberg, “The Art of Adaptive Pattern     Recognition by a Self-Organizing Neural Network”, IEEE Computer,     March 1988, pp. 77–88. -   Casasent, D., et al., “General I and Q Data Processing on a     Multichannel AO System”, Applied Optics, 25(18):3217–24 (Sep. 15,     1986). -   Caudill, M., “Neural Networks Primer-Part HII”, AI Expert, June     1988, pp. 53–59. -   Chao, J. J., E. Drakopoulos, C. C. Lee, “An evidential reasoning     approach to distributed multiple hypothesis detection”, Proceedings     of the 20th Conference on decision and control, Los Angeles, Calif.,     December 1987. -   Chao, T.-H.; Hegblom, E.; Lau, B.; Stoner, W. W.; Miceli, W. J.,     “Optoelectronically implemented neural network with a wavelet     preprocessor”, Proceedings of the SPIE—The International Society for     Optical Engineering, 2026:472–82(1993). -   Chen et al., “Adaptive Coding of Monochrome and Color Images”,     November 1977, pp. 1285–1292. -   Cheong, C. K.; Aizawa, K.; Saito, T.; Hatori, M., “Adaptive edge     detection with fractal dimension”, Transactions of the Institute of     Electronics. Information and Communication Engineers D-II,     J76D-II(11):2459–63 (1993). -   Computer Visions, Graphics, and Image Processing, 1987, 37:54–115. -   Computers and Biomedical Research 5, 388–410 (1972). -   Cooper, L. N., “A Possible Organization of Animal Memory and     Learning”, Nobel 24, (1973), Collective Properties of Physical     Systems, pp. 252–264. -   Crawford et al., “Adaptive Pattern Recognition Applied To An Expert     System For Fault Diagnosis In Telecommunications Equipment”, pp.     10/1–8 (Inspec. Abstract No. 86C010699, Inspec IEE (London) & IEE     Coll. on “Adaptive Filters”, Digest No. 76, Oct. 10, 1985). -   Danielsson, Erik, et al., “Computer Architectures for Pictorial Inf.     Systems”, IEEE Computer, November, 1981, pp. 53–67. -   Dempster, A. P., “A generalization of Bayesian inference”, Journal     of the Royal Statistical Society, Vol. 30, Series B (1968). -   Dempster, A. P., “Upper and lower probabilities induced by a     multivalued mapping”, Annals of mathematical Statistics, no. 38     (1967). -   Denker, 1984 International Test Conf., October 1984, Philadelphia,     Pa., pp. 558–563. -   Dubois, D., “Modeles mathematiques de l'imprecis et de l'incertain     en vue d'applications aux techniques d'aide a la decision”, Doctoral     Thesis, University of Grenoble (1983). -   Dubois, D., N. Prade, “Combination of uncertainty with belief     functions: a reexamination”, Proceedings 9th International Joint     Conference on Artificial Intelligence, Los Angeles (1985). -   Dubois, D., N. Prade, “Fuzzy sets and systems-Theory and     applications”, Academic Press, New York (1980). -   Dubois, D., N. Prade, “Theorie des possibilites: application a la     representation des connaissances en informatique”, Masson, Paris     (1985). -   Duda, R. O., P. E. Hart, M. J. Nilsson, “Subjective Bayesian methods     for rule-based inference systems”, Technical Note 124, Artificial     Intelligence Center, SRI International. -   Dunning, B. B., “Self-Learning Data-Base For Automated Fault     Localization”, IEEE, -   1979, pp. 155–157. -   Farrelle, Paul M. and Jain, Anil K., “Recursive Block Coding—A New     Approach to Transform Coding”, IEEE Transactions on Communications,     Corn. 34(2) (February 1986). -   Fitzpatrick, J. M., J. J. Grefenstette, D. Van Gucht, “Image     Registration by Genetic Search”, Conf. Proc., IEEE Southeastcon     1984, pp. 460–464. -   Fua, P. V., “Using probability density functions in the framework of     evidential reasoning Uncertainty in knowledge based systems”, B.     Bouchon, R. R. Yager, Eds. Springer Verlag (1987). -   Gogoussis et al., Proc. SPIE Intl. Soc. Opt. Eng., November 1984,     Cambridge, Mass., pp. 121–127. -   Grossberg, S., G. Carpenter, “A Massively Parallel Architecture for     a Self-Organizing Neural Pattern Recognition Machine”, Computer     Vision, Graphics, and Image Processing, 1987, 37, 54–115, 252–315. -   Gullichsen, E., E. Chang, “Pattern Classification by Neural Network:     An Experiment System for Icon Recognition”, ICNN Proceeding on     Neural Networks, March 1987, pp. IV-725–32. -   Haruki, K. et al., “Pattern Recognition of Handwritten Phonetic     Japanese Alphabet Characters”, International Joint Conference on     Neural Networks, Washington, D.C., January 1990, pp. II-515 to     II-518. -   Hayashi, Y., et al., “Alphanumeric Character Recognition Using a     Connectionist Model with the Pocket Algorithm”, Proceedings of the     International Joint Conference on Neural Networks, Washington, D.C.     Jun. 18–22, 1989, vol. 2, pp. 606–613. -   Hayes, H. I.; Solka, J. L.; Priebe, C. E.; “Parallel computation of     fractal dimension”, Proceedings of the SPIE—The International     Society for Optical Engineering, 1962:219–30 (1993). -   Hinton et al., “Boltzmann Machines: Constraint Satisfaction Networks     that Learn”, Tech. Report CMU-CS-85-119, Carnegie-Mellon Univ, May     1984. -   Hoare, F.; de Jager, G., “Neural networks for extracting features of     objects in images as a pre-processing stage to pattern     classification”, Proceedings of the 1992 South African Symposium on     Communications and Signal Processing. COMSIG '92 (Cat. No.     92TH0482-0). Inggs, M. (Ed.), p. 239–42 (1992). -   Hopfield et al., “Computing with Neural Circuits: A Model”, Science.     233:625–633 (8 Aug. 1986). -   Hopfield, “Neural Networks and Physical Systems with Emergent     Collective Computational Abilities”, Proc. Natl. Acad. Sci. USA,     79:2554–2558 (April 1982). -   Hopfield, “Neurons with graded response have collective     computational properties like those of two-state neurons”, Proc.     Natl. Acad. Sci. USA, 81:3088–3092 (May 1984). -   Hurtgen, B.; Buttgen, P., “Fractal approach to low rate video     coding”, Proceedings of the SPIE—The International Society for     Optical Engineering, 2094(pt.1):120–31(1993). -   Information Processing 71, North-Holland Publishing Company (1972)     pp. 1530–1533. -   Ishizuka, M., “Inference methods based on extended Dempster and     Shafer's theory for problems with uncertainty/fuzziness”, New     Generation Computing, Ohmsha, Ltd, and Springer Verlag, 1:159–168     (1983). -   Jackel, L. D., H. P. Graf, J. S. Denker, D. Henderson and I. Guyon,     “An Application of Neural Net Chips: Handwritten Digit Recognition”,     ICNN Proceeding, 1988, pp. II-107–15. -   Jean, J. S. N., et al., “Input Representation and Output Voting     Considerations for Handwritten Numeral Recognition with     Backpropagation”, International Joint Conference on Neural Networks,     Washington, D.C., January 1990, pp. I-408 to I-411. -   Jeffrey, R. J., “The logic of decision”, The University of Chicago     Press, Ltd., London (1983)(2nd Ed.). -   Kaufmann, A., “Introduction a la theorie des sous-ensembles flous”,     Vol. 1, 2 et 3, Masson, Paris (1975). -   Keeney, R. L., B. Raiffa, “Decisions with multiple objectives:     Preferences and value tradeoffs”, John Wiley and Sons, New York     (1976). -   Kellman, P., “Time Integrating Optical Signal Processing”, Ph. D.     Dissertation, Stanford University, 1979, pp. 51–55. -   Kim, D. H.; Caulfield, H. J.; Jannson, T.; Kostrzewski, A.; Savant,     G, “Optical fractal image processor for noise-embedded targets     detection”, Proceedings of the SPIE—The International Society for     Optical Engineering, Vol: 2026 p. 144–9 (1993) (SPIE Conf: Photonics     for Processors, Neural Networks, and Memories 12–15 July 1993, San     Diego, Calif., USA). -   Kohonen, “Self-Organization & Memory”, Second Ed., 1988,     Springer-Verlag, pp. 199–209. -   Kortegaard, B. L., “PAC-MAN, a Precision Alignment Control System     for Multiple Laser Beams Self-Adaptive Through the Use of Noise”,     Los Alamos National Laboratory, date unknown. -   Kortegaard, B. L., “Supene Laser Position Control Using     Statistically Enhanced Resolution in Real Time”, Los Alamos National     Laboratory, SPIE-Los Angeles Technical Symposium, Jan. 23–25, 1985. -   Ksienski et al., “Low Frequency Approach to Target Identification”,     Proc. of the IEEE, 63(12):1651–1660 (December 1975). -   Kyburg, H. E., “Bayesian and non Bayesian evidential updating”,     Artificial Intelligence 31:271–293 (1987). -   LeCun, Y. et al., “Handwritten Digit Recognition: Applications of     Neural.”, IEEE Comm. Magazine, November 1989, pp. 41–46. -   LeCun, Y., “Connectionism in Perspective”, in R. Pfeifer, Z.     Schreter, F. Fogelman, L. Steels (Eds.), 1989, “Generalization and     Network Design Strategies”, pp. 143–155. -   Liepins, G. E., M. R. Hilliard, “Genetic Algorithms: Foundations &     Applications”, Annals of Operations Research, 21:31–58 (1989). -   Lin, H. K., et al., “Real-Time Screen-Aided Multiple-Image Optical     Holographic Matched-Filter Correlator”, Applied Optics,     21(18):3278–3286 (Sep. 15, 1982). -   Lippman, R. P., “An Introduction to Computing with Neural Nets”,     IEEE ASSP Magazine, April 1987, pp. 4–22. -   Lippmann, R. P., “An Introduction to Computing with Neural Nets”,     IEEE ASSP Magazine, vol. 4(2):4–22 (April 1987). -   Liu, Y., “Extensions of fractal theory”, Proceedings of the SPIE—The     International Society for Optical Engineering, 1966:255–68(1993). -   Liu, Y., “Pattern recognition using Hilbert space”, Proceedings of     the SPIE—The International Society for Optical Engineering,     1825:63–77 (1992). -   Mahalanobis, A., et al., “Minimum Average Correlation Energy     Filters”, Applied Optics, 26(17):3633–40 (Sep. 1, 1987). -   Martin, G. L. et al., “Recognizing Hand-Printed Letters and Digits     Using Backpropagation Learning”, Technical Report of the MCC, Human     Interface Laboratory, Austin, Tex., January 1990, pp. 1–9. -   McAulay, A. D., J. C. Oh, “Image Learning Classifier System Using     Genetic Algorithms”, IEEE Proc. of the National Aerospace &     Electronics Conference, 2:705–710 (1989). -   Miller, R. K., Neural Networks ((c) 1989: Fairmont Press, Lilburn,     Ga.), pp. 2–12 and Chapter 4, “Implementation of Neural Networks”,     pp. 4-1 to 4-26. -   Motley, P., “Implementing the Difference-Squared Error Algorithm     Using An Acousto-Optic Processor”, SPIE, 1098:232–239 (1989). -   Motley, P., et al., “A High Dynamic Range Acousto-Optic Image     Correlator for Real-Time Pattern Recognition”, SPWE, 938:55–65     (1988). -   Mori, “Towards the construction of a large-scale neural network”,     Electronics Information Communications Association Bulletin PRU     88-59, pp. 87–94. -   Naik et al., “High Performance Speaker Verification.”, ICASSP 86,     Tokyo, CH2243-4/86/0000-0881, IEEE 1986, pp. 881–884. -   Ney, H., et al., “A Data Driven Organization of the Dynamic     Programming Beam Search for Continuous Speech Recognition”, Proc.     ICASSP 87, pp. 833–836, 1987. -   Nilsson, N. J., The Mathematical Foundations of Learning Machines     ((c) 1990: Morgan Kaufmann Publishers, San Mateo, Calif.) and     particularly section 2.6 “The Threshold Logic Unit (TLU)”, pp. 21–23     and Chapter 6, “Layered Machines” pp. 95–114. -   Ohsuga et al., “Entrainment of Two Coupled van der Pot Oscillators     by an External Oscillation”, Biological Cybernetics, 51:225–239     (1985). -   Omata et al., “Holonic Model of Motion Perception”, IEICE Technical     Reports, Mar. 26, 1988, pp. 339–346. -   O'Neal et al., “Coding Isotropic Images”, November 1977, pp.     697–707. -   Pawlicki, T. F., D. S. Lee, J. J. Hull and S. N. Srihari, “Neural     Network Models and their Application to Handwritten Digit     Recognition”, ICNN Proceeding, 1988, pp. II-63–70. -   Perry et al., “Auto-Indexing Storage Device”, IBM Tech. Disc.     Bulletin, 12(8):1219 (January 1970). -   Peterson, Ivars, “Packing It In”, Science News, 131(18):283–285 (May     2, 1987). -   Priebe, C. E.; Solka, J. L.; Rogers, G. W., “Discriminant analysis     in aerial images using fractal based features”, Proceedings of the     SPIE—The International Society for Optical Engineering,     1962:196–208(1993). -   Proceedings, 6th International Conference on Pattern Recognition     1982, pp. 152–136. -   Psaltis, D., “Incoherent Electro-Optic Image Correlator”, Optical     Engineering, 23(1):12–15 (January/February 1984). -   Psaltis, D., “Two-Dimensional Optical Processing Using     One-Dimensional Input Devices”, Proceedings of the IEEE,     72(7):962–974 (July 1984). -   Rahmati, M.; Hassebrook, L. G., “Intensity- and distortion-invariant     pattern recognition with complex linear morphology”, Pattern     Recognition, 27 (4):549–68(1994). -   Reusens, E., “Sequence coding based on the fractal theory of     iterated transformations systems”, Proceedings of the SPIE—The     International Society for Optical Engineering,     2094(pt.1):132–40(1993). -   Rhodes, W., “Acousto-Optic Signal Processing: Convolution and     Correlation”, Proc. of the IEEE, 69(1):65–79 (January 1981). -   Rosenfeld, Azriel and Avinash C. Kak, Digital Picture Processing,     Second Edition, Volume 2, Academic Press, 1982. -   Roy, B., “Classements et choix en presence de points de vue     multiples”. R.I.R.O.-2eme annee-no. 8, pp. 57–75 (1968). -   Roy, B., “Electre III: un algorithme de classements fonde sur une     representation floue des preferences en presence de criteres     multiples”, Cahiers du CERO, 20(1):3–24 (1978). -   Rumelhart, D. E., et al., “Learning Internal Representations by     Error Propagation”, Parallel Distr. Proc.: Explorations in     Microstructure of Cognition, 1:318–362 (1986). -   Rumeihart, D. E., et al., Parallel Distributed Processing, ((c)     1986: MIT Press, Cambridge, Mass.), and specifically Chapter 8     thereof, “Learning Internal Representations by Error Propagation”,     pp. 318–362. -   Rutherford, H. G., F. Taub and B. Williams, “Object Identification     and Measurement from Images with Access to the Database to Select     Specific Subpopulations of Special Interest”, May 1986. -   Rutter et al., “The Timed Lattice—A New Approach To Fast Converging     Equalizer Design”, pp.VIII/1–5 (Inspec. Abstract No. 84C044315,     Inspec IEE (London) & IEE Saraga Colloquium on Electronic Filters,     May 21, 1984). -   Sadjadi, F., “Experiments in the use of fractal in computer pattern     recognition”, Proceedings of the SPIE—The International Society for     Optical Engineering, 1960:214–22(1993). -   Sakoe, H., “A Generalization of Dynamic Programming Based Pattern     Matching Algorithm Stack DP-Matching”, Transactions of the Committee     on Speech Research, The Acoustic Society of Japan, p. S83–23, 1983. -   Sakoe, H., “A Generalized Two-Level DP-Matching Algorithm for     Continuous Speech Recognition”, Transactions of the IECE of Japan,     E65(11):649–656 (November 1982). -   Scharlic, A., “Decider sur plusieurs criteres. Panorama de l'aide a     la decision multicritere”, Presses Polytechniques Romandes (1985). -   Schurmann, J., “Zur Zeichen und Worterkennung beim Automatischen     Anschriftenlesen”, Wissenschaftlichl, Berichte, 52(1/2) (1979). -   Scientific American, “Not Just a Pretty Face”, March 1990, pp.     77–78. -   Shafer, G., “A mathematical theory of evidence”, Princeton     University Press, Princeton, N.J. (1976). -   Shimizu et al., “Principle of Holonic Computer and Holovision”,     Journal of the Institute of Electronics, Information and     Communication, 70(9):921–930 (1987). -   Shinan et al., “The Effects of Voice Disguise.”, ICASSP 86, Tokyo,     CH2243-4/86/0000-0885, IEEE 1986, pp. 885–888. -   Silverston et al., “Spectral Feature Classification and Spatial     Pattern Rec.”, SPIE 201:17–26, Optical Pattern Recognition (1979). -   Simpson, W. R., C. S. Dowling, “WRAPLE: The Weighted Repair     Assistance Program Leaming Extension”, IEEE Design & Test, 2:66–73     (April 1986). -   Specht, IEEE Internatl. Conf. Neural Networks, 1:1525–1532 (July     1988), San Diego, Calif. -   Sprageu, R. A., “A Review of Acousto-Optic Signal Correlators”,     Optical Engineering, 16(5):467–74 (September/October 1977). -   Sprinzak, J.; Werman, M., “Affine point matching”, Pattern     Recognition Letters, 15(4):337–9(1994). -   Stanley R. Sternberg, “Biomedical Image Processing”, IEEE Computer,     1983, pp. 22–34. -   Stewart, R. M., “Expert Systems For Mechanical Fault Diagnosis”,     IEEE, 1985, pp. 295–300. -   Sugeno, M., “Theory of fuzzy integrals and its applications”. Tokyo     Institute of Technology (1974). -   Svetkoff et al., Hybrid Circuits (GB), No. 13, May 1987, pp. 5–8. -   Udagawa, K., et al, “A Parallel Two-Stage Decision Method for     Statistical Character Recognition.”, Electronics and Communications     in Japan (1965). -   Vander Lugt, A., “Practical Considerations for the Use of Spatial     Carrier-Frequency Filters”, Applied Optics, 5(11): 1760–1765     (November 1966). -   Vander Lugt, A., “Signal Detection By Complex Spatial Filtering”,     IEEE Transactions On Information Theory, IT-10, 2:139–145 (April     1964). -   Vander Lugt, A., et al., “The Use of Film Nonlinearites in Optical     Spatial Filtering”, Applied Optics, 9(1):215–222 (January 1970). -   Vannicola et al., “Applications of Knowledge Based Systems to     Surveillance”, Proceedings of the 1988 IEEE National Radar     Conference, 20–21 April 1988, pp. 157–164. -   Vitols, “Hologram Memory for Storing Digital Data”, IBM Tech. Disc.     Bulletin 8(11):1581–1583 (April 1966). -   Wald, Sequential Analysis, Dover Publications Inc., 1947, pp. 34–43. -   Wasserman, Philip D., “Neural Computing-Theory & Practice”, 1989,     pp. 128–129. -   Willshaw et al., “Non-Holographic Associative Memory”, Nature,     222:960–962 (Jun. 7, 1969). -   Yager, R. R., “Entropy and specificity in a mathematical theory of     Evidence”, Int. J. General Systems, 9:249–260 (1983). -   Yamada et. al., “Character recognition system using a neural     network”, Electronics Information Communications Association     Bulletin PRU 88–58, pp. 79–86. -   Yamane et al., “An Image Data Compression Method Using     Two-Dimensional Extrapolative Prediction-Discrete Sine Transform”,     Oct. 29–31, 1986, pp. 311–316. -   Zadeh, L. A., “Fuzzy sets as a basis for a theory of possibility”,     Fuzzy sets and Systems, 1:3–28 (1978). -   Zadeh, L. A., “Fuzzy sets”, Information and Control, 8:338–353     (1965). -   Zadeh, L. A., “Probability measures of fuzzy events”, Journal of     Mathematical Analysis and Applications, 23:421–427 (1968). -   Zhi-Yan Xie; Brady, M., “Fractal dimension image for texture     segmentation”, ICARCV '92. Second International Conference on     Automation, Robotics and Computer Vision, p. CV-4.3/1–5 vol. 1,     (1992). -   Zhu, X., et al., “Feature Detector and Application to Handwritten     Character Recognition”, International Joint Conference on Neural     Networks, Washington, D.C., January 1990, pp. II-457 to II-460.

The above-mentioned references are exemplary, and are not meant to be limiting in respect to the resources and/or technologies available to those skilled in the art. Of course it should be realized that the hardware for implementing a system may be integrally related to the choice of specific method or software algorithm for implementing the system, and therefore these together form a system. It is noted that in view of the present disclosure, it is within the skill of the artisan to combine in various fashions the available methods and apparatus to achieve the advanced interface and control system of the present invention.

SUMMARY AND OBJECTS OF THE INVENTION

The present invention provides, according to one embodiment, an adaptive user interface which changes in response to the context, past history and status of the system. The strategy employed preferably seeks to minimize, for an individual user at any given time, the search and acquisition time for the entry of data through the interface.

The interface may therefore provide a model of the user, which is employed in a predictive algorithm. The model parameters may be static (once created) or dynamic, and may be adaptive to the user or alterations in the use pattern.

The present invention also provides a model-based pattern recognition system, for determining the presence of an object within an image. By providing models of the objects within an image, the recognition process is relatively unaffected by perspective, and the recognition may take place in a higher dimensionality space than the transmitted media. Thus, for example, a motion image may include four degrees of freedom; x, y, chroma/luma, and time. A model of an object may include further dimensions, including z, and axes of movement. Therefore, the model allows recognition of the object in its various configurations and perspectives.

A major theme of the present invention is the use of intelligent, adaptive pattern recognition in order to provide the operator with a small number of high probability choices, which may be complex, without the need for explicit definition of each atomic instruction comprising the desired action. The interface system predicts a desired action based on the user input, a past history of use, a context of use, and a set of predetermined or adaptive rules.

Because the present invention emphasizes adaptive pattern recognition of both the input of the user and data which may be available, the interface system proposes the extensive use of advanced signal processing and neural networks. These processing systems may be shared between the interface system and the functional system, and therefore a controller for a complex system may make use of the intrinsic processing power available rather than requiring additional computing power, although this unification is not required. In the case where the user interface employs common hardware elements, it is further preferred that the interface subsystem employ common models of the underlying data structures on which the device functionally operates.

In fact, while hardware efficiency dictates common hardware for the interface system and the operational routine, other designs may separate the interface system from the operational system, allowing portability and efficient application of a single interface system for a number of operational systems. Thus, the present invention also proposes a portable human interface system which may be used to control a number of different devices. In this case, a web browser metaphor is preferred, as it has become a standard for electronic communications.

A portable interface may, for example, take the form of a personal digital assistant or downloaded JAVA applet, with the data originating in a web server. The data from a web server or embedded web server may include a binary file, a generic HTML/XML file, or other data type. The interface receives the data and formats it based, at least in part, on parameters specific to the client or user. Thus, the presentation of data is responsive to the user, based on user preferences, as opposed to hardware limitations or compatibility issues. In a preferred embodiment, the data is transmitted separately from the presentation definition. The presentation definition, on the other hand, provides a set of parameters that propose or constrain the data presentation. The user system also provides a set of parameters that set preferences on presentation. Further, the data itself is analyzed for appropriate presentation parameters. These three sets of considerations are all inputs into a “negotiation” for an ultimate presentation scheme. Thus, the presentation is adaptive to server parameters, user parameters, and the data itself. For example, in a typical web-context, the color, size, typestyle, and layout of text may be modified based on these considerations. Other factors that may be altered include frame size and layout, size of hotspots, requirement for single or double clicks for action, and the like.

The adaptive nature of the present invention derives from an understanding that people learn most efficiently through the interactive experiences of doing, thinking, and knowing. For ease-of-use, efficiency, and lack of frustration of the user, the interface of the device should be intuitive and self explanatory, providing perceptual feedback to assist the operator in communicating with the interface, which in turn allows the operational system to receive a description of a desired operation. Another important aspect of man-machine interaction is that there is a learning curve, which dictates that devices which are especially easy to master become frustratingly elemental after continued use, while devices which have complex functionality with many options are difficult to master and may be initially rejected, or the user stops exploring. One such system which addresses this problem is U.S. Pat. No. 5,005,084, expressly incorporated herein by reference. The present invention addresses these issues by determining the most likely instructions of the operator, and presenting these as easily available choices, by analyzing the past history data and by detecting the “sophistication” of the user in performing a function, based on all information available to it. The context of use may also be a significant factor. The interface seeks to optimize the relevant portion of the interface adaptively and immediately in order to balance and optimize the interface for both quantitative and qualitative factors. This functionality may greatly enhance the quality of interaction between man and machine, allowing a higher degree of overall system sophistication to be tolerated and a greater value added than other interface designs. See, Commaford, C., “User-Responsive Software Must Anticipate Our Needs”, PC Week, May 24, 1993.

The present interface system analyzes data from the user, which may be both the selections made by the user in context, as well as the efficiency by which the user achieves the selection. Thus, information concerning both the endpoints and time-dependent path of the process are considered and analyzed by the interface system.

The interface of the present invention may be advantageously applied to an operational system that has a plurality of functions, certain of which are unnecessary or are rarely used in various contexts, while others are used with greater frequency. In such systems, the functionality use is usually predictable. Therefore, the present invention provides an optimized interface system which, upon recognizing a context, dynamically reconfigures the availability or ease of availability of functions and allow various subsets to be used through “shortcuts”. The interface presentation will therefore vary over time, use and the particular user.

The advantages to be gained by using an intelligent data analysis interface for facilitating user control and operation of the system are more than merely reducing the average number of selections or time to access a given function. Rather, advantages also arise from providing a means for access and availability of functions not necessarily previously existing or known to the user, therefore improving the perceived quality and usefulness of the product. Further advantages over prior interfaces accrue due to the availability of pattern recognition functionality as a part of the interface system.

In those cases where the pattern recognition functions are applied to large amounts of data or complex data sets, in order to provide a sufficient advantage and acceptable response time, powerful computational resources, such as advanced DSPs or neural network processors are made available to the interface system. On the other hand, where the data is simple or of limited scope, aspects of the technology may be easily implemented as added software functionality as improvements of existing products having limited computational resources.

The application of these technologies to multimedia systems provides a new model for performing image pattern recognition on multimedia data and for the programming of applications including such data. The ability of the interface of the present invention to perform abstractions and make decisions regarding a closeness of presented data to selection criteria makes the interface suitable for use in a programmable control, i.e., determining the existence of certain conditions and taking certain actions on the occurrence of detected events. Such advanced technologies might be especially valuable for disabled users.

In a multimedia environment, a user often wishes to perform an operation on a multimedia data event. Past systems have required explicit indexing of images and events. The present technologies, however, allow an image, diagrammatic, abstract or linguistic description of the desired event to be acquired by the interface system from the user and applied to identify or predict the multimedia event(s) desired without requiring a separate manual indexing or classification effort. These technologies may also be applied to single media data.

The interface system according to the present invention is not limited to a single data source, and may analyze data from many different sources for its operation. This data may be stored data or present in a data stream. Thus, in a multimedia system, there may be a real-time data stream, a stored event database, as well as an exemplar or model database. Further, since the device is adaptive, information relating to past experience of the interface, both with respect to exposure to data streams and user interaction, is also stored. This data analysis aspect of the operation of the present interface system may be substantially processor intensive, especially where the data includes abstract or linguistic concepts or images to be analyzed. Interfaces which do not relate to the processing of such data may be implemented on simpler hardware. On the other hand, systems which handle complex data types may necessarily include sophisticated processors, adaptable for use with the interface system, thus minimizing the additional computing power necessary in order to implement the interface according to the present invention. A portion of the data analysis may also overlap the functional analysis of the data for operation.

A fractal-based image processing system exemplifies one application of the technologies. A fractal-based system includes a database of image objects, which may be preprocessed in a manner which makes them suitable for comparison to a fractal-transformed image representation of an image to be analyzed. Thus, corresponding “fractal” transforms are performed on the unidentified image or a portion thereof and on an exemplar of a database. A degree of relatedness is determined in this “fractal transform domain”, and the results used to identify objects within the image. The system then makes decisions based on the information content of the image, i.e. the objects contained therein.

The fractal-based image processing system presents many advantages. First, fractal-processed images may have dramatically reduced storage size requirements as compared to traditional methods while substantially retaining information important for image recognition. The process may be parallelized, and the exemplars may be multidimensional, further facilitating the process of identifying a two-dimensional projection of an object. The efficient storage of information allows the use of inexpensive storage media, i.e., CD-ROM, or the use of an on-line database through a serial data link, while allowing acceptable throughput. See, Zenith Starsight Telecast brochure, (1994); U.S. Pat. No. 5,353,121, expressly incorporated herein by reference.

As applied to a multimedia database storage and retrieval system, the user programs, through an adaptive user interface according to the present invention, the processing of data, by defining a criteria and the actions to be taken based on the determination of the criteria. The criteria, it is noted, need not be of a predefined type, and in fact this is a particular feature of the present invention. A pattern recognition subsystem is employed to determine the existence of selected criteria. To facilitate this process, a database of image objects may be stored as two counterparts: first, the data is stored in a compressed format optimized for normal use, such as human viewing on a video monitor, using, e.g., MPEG-2 or Joint Photographic Experts Group (JPEG) compression; second, it is stored in a preprocessed and highly compressed format adapted to be used with the pattern recognition system. Because the preprocessed data is highly compressed and used directly by the pattern recognition system, great efficiencies in storage and data transmission are achieved. The image preprocessing may include Fourier, DCT, wavelet, Gabor, fractal, or model-based approaches, or a combination thereof.

The potential significant hardware requirement for image processing and pattern recognition is counterbalanced by the enhanced functionality available by virtue of the technologies. When applied to multimedia devices, the interface system allows the operator to define complex criteria with respect to image, abstract or linguistic concepts, which would otherwise be difficult or impossible to formulate. Thus, the interface system becomes part of a computational system that would otherwise be too cumbersome for use. It is noted that, in many types of media streams, a number of “clues” are available defining the content, including close caption text, electronic program guides, simulcast data, related Internet web sites, audio tracks, image information, and the like. The latter two data types require difficult processing in order to extract a semantic content, while the former types are inherently semantic data.

A pattern recognition subsystem allows a “description” of an “event” without explicit definition of the data representing the “event”. Thus, instead of requiring explicit programming, an operator may merely define parameters of the desired “event”. This type of system is useful, for example, where a user seeks a generic type of data representing a variety of events. This eliminates the need for preindexing or standardized characterization of the data. The interface system therefore facilitates the formulation of a request, and then searches the database for data which corresponds to the request. Such preindexing or standardized characterization is extremely limiting with image and multimedia data, because “a picture is worth a thousand words”, and without a priori knowing the ultimate search criteria, all possible criteria must be accounted for. Pattern recognition systems do not require initial translation of visual aspects into linguistic concepts, thus allowing broader searching capability. Of course, a pattern recognition system may be used in conjunction with other searching schemes, to mutual advantage.

The pattern recognition functionality of the interface system is not limited to multimedia data, and may be applied to data of almost any type, e.g., real-time sensor data, distributed control, linguistic data, etc.

It is noted that, in consumer electronics and particularly entertainment applications, the reliability of the system need not be perfect, and errors may be tolerable. On the other hand, in industrial control applications, reliability must be much higher, with fail-safe backup systems in place, as well as advanced error checking. One way to address this issue is to allow the advanced user interface to propose an action to the user, without actually implementing the action. However, in this case, the action and its proposed basis are preferably presented to the user in a sophisticated manner, to allow the basis for the action to be independently assessed by the user. Therefore, in a complex, multistep process, the user interface may be simplified by permitting a three step process: the user triggers a proposed response, analyzes the proposal and rationale, and confirms the proposal. Therefore, single step processes are inferior candidates for intelligent assistance.

Another notable aspect of the technologies is the contextual analysis. Often, multimedia data often includes a data component that closely corresponds to a format of a search criteria. Thus, while a search may seek a particular image, other portions of the datastream correlate well with the aspect of the image being searched, and may be analyzed by proxy, avoiding the need for full image analysis. The resulting preselected reduced number of images may then be fully analyzed, if necessary. Thus, especially as with respect to consumer electronics applications, where absolute accuracy may not be required, the processing power available for pattern recognition need not be sufficient for compete real-time signal analysis of all data. The present invention therefore proposes use of a variety of available data in order to achieve the desired level functionality at minimum cost.

One aspect of the present invention therefore relates to a mechanism for facilitating a user interaction with a programmable device. The interface and method of use of the present invention serves to minimize the learning and searching times, better reflect users' expectations, provide better matching to human memory limits, be usable by both novices and experienced users, reduce intimidation of novice users by the device, reduce errors and simplify the entering of programming data. The present invention optimizes the input format scheme for programming an event-driven device, and can also be applied to many types of programmable devices. Thus, certain human factors design concepts, heretofore unexploited in the design of consumer electronics devices and industrial controls, have been incorporated, and new precepts developed. Background and theory of various aspects of the present invention is disclosed in “AN IMPROVED HUMAN FACTORED INTERFACE FOR PROGRAMMABLE DEVICES: A CASE STUDY OF THE VCR”, Master's Thesis, Tufts University (Master of Sciences in Engineering Design, November, 1990, publicly available January. 1991), by Linda I. Hoffberg. This thesis, and cited references, are incorporated herein by reference, and attached hereto as an appendix. Also referenced are: Hoffberg, Linda I., “Designing User Interface Guidelines For Time-Shift Programming of a Video Cassette Recorder (VCR)”, Proc. of the Human Factors Soc. 35th Ann. Mtg. pp. 501–504 (1991); and Hoffberg, Linda I., “Designing a Programmable Interface for a Video Cassette Recorder (VCR) to Meet a User's Needs”. Interface 91 pp. 346–351 (1991). See also, U.S. patent application Ser. No. 07/812,805, filed Dec. 23, 1991, incorporated herein by reference in its entirety, including appendices and incorporated references.

The present invention extends beyond simple predictive schemes which present exclusively a most recently executed command or most recently opened files. Thus, the possible choices are weighted in a multifactorial method, e.g., history of use, context and system status, rather than a single simple criterion alone. Known simple predictive criteria often exclude choices not previously selected, rather than weighing these choices in context with those which have been previously selected. While the system according to the present invention may include initial weightings, logical preferences or default settings, through use, the derived weightings are obtained adaptively based on an analysis of the status, history of use and context. It is noted that not all of the possible choices need be weighted, but rather merely a subset thereof.

For a given system, status, history of use and context may be interrelated factors. For example, the status of the machine is determined by the prior use, while the status also intersects context. The intended meaning of status is information relating to a path independent state of the machine at a given point in time. History of use is intended to implicate more than the mere minimum instructions or actions necessary to achieve a given state, and therefore includes information unnecessary to achieve a given state, i.e., path dependent information. Context is also related to status, but rather is differentiated in that context refers to information relating to the environment of use, e.g., the variable inputs or data upon which the apparatus acts or responds. Status, on the other hand, is a narrower concept relating more to the internal and constant functionality of the apparatus, rather than the particularities of its use during specific circumstances.

U.S. Pat. No. 5,187,797 relates to a machine interface system having hierarchical menus, with a simple (three button) input scheme. The choice(s) presented relate only to the system status, and not the particular history of use employed to obtain the system status nor the context of the choice. This system has a predetermined hierarchical menu structure, which is invariant with usage. The goal of this interface system is not to provide a learning interface, but rather to teach the user about or conform the user to the dictates of the predetermined and invariant interface of the device. While many types of programmable devices are known to exist, normally, as provided in U.S. Pat. No. 5,187,797, instructions are entered and executed in a predetermined sequence, with set branch points based on input conditions or the environment. See also U.S. Pat. Nos. 4,878,179, 5,124,908, and 5,247,433.

An aspect of the present invention provides a device having a predetermined or a generic style interface upon initial presentation to the user, with an adaptive progression in which specialized features become more easily available to a user who will likely be able to make use of them, while unused features are or remain “buried” within the interface. The interface also extracts behavioral information from the user and to alter the interface elements to optimize the efficiency of the user.

A videocassette recorder is a ubiquitous example of a programmable device, and therefore forms the basis of much of the discussion herein. It should, of course, be realized that many of the aspects of the present invention could be applied by one of ordinary skill in the art to a variety of controls having human interfaces, and that these other applications are included within the scope of the present invention.

The VCR apparatus typically involves a remote control entry device, and the interface of the present invention contains a graphical interface displayed for programming programmable devices. This aspect of the present invention seeks more accurate programming through the use of program verification to ensure that the input program is both valid and executable. Thus, it has a mechanism to store and check to verify that there are no conflicting programs. An apparatus according to the present invention can be connected, for example, to any infrared programmable device in order to simplify the programming process. By way of example only, an improved VCR interface forms the basis of a disclosed example. It is, of course, realized that the present method and apparatus may be applied to any programmable controller, i.e., any device which monitors an event or sensor and causes an event when certain conditions or parameters are met, and may also be used in other programming environments, which are not event driven. While the present interface is preferably learning and adaptive, it may also detect events and make decisions based on known or predetermined characteristics. Where a number of criteria are evaluated for making a decision, conflicts among the various criteria are resolved based on a strength of an evaluated criteria, a weighting of the criteria, an interactivity function relating the various criteria, a user preference, either explicitly or implicitly determined, and a contextual analysis. Thus, a user override or preference input may be provided to assist in resolving conflicts.

The present invention may incorporate an intelligent program recognition and characterization system, making use of any of the available cues, which allows an intelligent determination of the true nature of the broadcast and therefore is able to make a determination of whether parameters should be deemed met even with an inexact match to the specified parameters. Therefore, in contradistinction with VPV, the present invention provides, for example, intelligence. The VPV is much more like the “VCR Plus” device, known to those skilled in the art, which requires that a broadcast be associated with a predetermined code, with the predetermined code used as a criteria for initiating recording. Some problems with VCR Plus include identification of the codes which identify channel and time, post scheduling changes, incorrect VCR clock setting, and irregular schedules. VCR Plus also is limiting with respect to new technologies and cable boxes.

The videotext signal of the prior art includes a digitally encoded text message that may be displayed in conjunction with the displayed image, similar to the closed caption system. The aforementioned West German system demonstrates one way in which the transmitted signal may be received by a device and interpreted to provide useful information other than the transmitted program itself. However, the prior art does not disclose how this signal may be used to index and catalog the contents of a tape, nor does it disclose how this signal may be used to classify or interpret the character of the broadcast. In other words, in one embodiment of the present invention, the videotext or closed caption signal is not only interpreted as a literal label, as in the prior art, but is also further processed and analyzed to yield data about the content of the broadcast, other than merely an explicit identification of the simultaneously broadcast information.

Beyond or outside the visible region of an U.S. National Television Standards Committee (NTSC) broadcast video frame are a number of scan lines which are dedicated to presenting digital information, rather than analog picture information. Various known coding schemes are available for transmitting and receiving information in this non-viewing portion of the video transmission, and indeed standard exist defining the content of these information fields. Of course, various other transmission schemes provide a format for transmitting data. For example, standard frequency modulation (FM) transmissions may be associated with digital data transmissions in a subcarrier. Likewise, satellite transmissions may include digital data along with an audio data stream or within a video frame, which may be in analog format or digitally encoded.

Cable systems may transmit information either in the broadcast band or in a separate band. HDTV schemes also generally provide for the transmission of digital data of various sorts. Thus, known audio and video transmission systems may be used, with little or no modifications to provide enhanced functionality, according to the present invention. It is therefore possible to use known and available facilities for transmitting additional information relating to the broadcast information, in particular, the characteristics of the video broadcast, and doing so could provide significant advantages, used in conjunction with the interface and intelligent pattern recognition controller of the present invention. If this information were directly available, there would be a significantly reduced need for advanced image recognition functions, such advanced image recognition functions requiring costly hardware devices, while still maintaining the advantages of the present invention.

It is noted, however, that the implementation of a system in which characterization data of the broadcast is transmitted along therewith might require a new set of standards and the cooperation of broadcasters, as well as possibly the government regulatory and approval agencies. The present invention does not require, in all of its aspects, such standardization, and therefore may advantageously implement substantial data processing locally to the receiver. It is nevertheless within the scope of the invention to implement such a broadcast system with broadcast of characterization data in accordance with the present invention. Such broadcast characterization data may include characterizations as well as preprocessed data useful for characterizing according to flexible criteria in the local receiving device.

According to the present invention, if such characterizations are broadcast, they may, as stated above, be in band or out of band, e.g., making use of unused available spectrum bandwidth within the NTSC channel space, or other broadcast system channel space, or may be “simulcast” on a separate channel, such as an FM sideband or separate transmission channel. Use of a separate channel would allow a separate organization, other than the network broadcasters, to provide the characterization data for distribution to users of devices that make use of the present intelligent system for controlling a VCR or other broadcast information processing device. Thus, the characterization generating means need not be directly linked to the local user machine in order to fall within the scope of the present invention. The present invention also provides a mechanism for copyright holders or other proprietary interests to be protected, by limiting access to information be encryption or selective encryption, and providing an accounting system for determining and tracking license or broadcast fees.

Research has been performed relating to VCR usability, technology, implementation, programming steps, current technology, input devices, and human mental capacity. This research has resulted in a new paradigm for the entry of programming data into a sequential program execution device, such as a VCR, by casual users.

Four major problems in the interfaces of VCRs were found to exist. The first is that users spend far too much time searching for necessary information, which is necessary in order to complete the programming process. Second, many people do not program the VCR to record at a later time (time-shift) frequently, and thus forget the programming steps in the interim, i.e., the inter-session decay of the learning curve is significant. Third, the number of buttons on many remote control devices has become overwhelming. Fourth, people have become reluctant to operate or program VCRs because of their difficult operation. It was found that, by minimizing the learning and searching times, the user's programming time and frustration level can be greatly reduced. If VCRs are easier to program, users might program them more frequently. This would allow more efficiency and flexibility in broadcast scheduling, especially late night for time shift viewing. The present invention therefore provides an enhanced VCR programming interface having a simplified information structure, an intuitive operational structure, simplified control layout and enhanced automated functionality.

A new class of consumer device has been proposed, which replaces the videotape of a traditional videotape recorder with a random-access storage device, such as a magnetic hard disk drive. Multimedia data is converted through a codec (if necessary), and stored in digital form. Such systems are proposed by Tivo, Inc., Philips Electronics (Personal TV), Replay Networks, Inc. and Metabyte, Inc. Some of these systems employ a user preference based programming/recording method similar to that of the present invention.

In these systems, typically a content descriptive data stream formulated by human editors accompanies the broadcast or is available for processing and analysis. Based on a relation of the user preferences, which may be implied by actual viewing habits or input through simple accept/veto user feedback, selected media events may be recorded. However, such systems rely on a correspondence between the factors of interest to users and those encoded in the data stream, e.g., a “program guide”. This is not always the case. However, where the available data describing the program maps reasonably well into the user preference space, such a system may achieve acceptable levels of performance, or stated otherwise, the program material selected by the system will be considered acceptable.

One particular aspect of these time-shifting consumer media recording devices is how they deal with advertising materials which accompany program material. In many instances, the user seeks to avoid “commercials”, and the device may be programmed to oblige. However, as such devices gain wider acceptance, advertisers will be reluctant to subsidize broadcasts. Therefore, an advertising system may be integrated into the playback device which seeks to optimize the commercial messages presented to a viewer. By optimizing the messages or advertisements, the viewer is more receptive to the message, and economic implications ensue. For example, a viewer may be compensated, directly or indirectly, for viewing the commercials, which may be closely monitored and audited, such as by taking pictures of the audience in front of a “set-top box”. The acquired data, including viewer preferences, may be transmitted back to commercial sponsors, allowing detailed demographic analysis.

In order to ensure privacy, the preference information and/or images may be analyzed by a proxy, with the raw data separated from the commercial users of such data. Thus, for example, the particular users of a system may register their biometric characteristics, e.g., face. Thereafter, the imager captures facial images and correlates these with its internal database. The image itself therefore need not be stored or transmitted. Viewer preferences and habits, on the other hand, likely must be transmitted to a central processing system for analysis.

Because the system is intelligent, copy protection and royalty accounting schemes may readily be implemented. Thus, broadcasters and content providers may encode broadcasts in such a way as to control the operation of the consumer device. For example, an IEEE-1394-type encryption key support/copy protection or DIVX scheme may be implemented. Further, certain commercial sponsors may be able to avoid deletion of their advertisement, while others may allow truncation. The acceptability of this to the consumer may depend on subsidies. In other words, an company is willing to pay for advertising. Instead of paying for placements directly to the media, a portion is paid to a service provider, based on consumer viewing. The media, on the other hand, may seek to adopt a pay-per-view policy, at least with respect to the service provider, in lieu of direct advertising revenues. The service provider will account to both advertisers and content providers for use. With sufficient viewing of commercials, the entire service charge for a system might be covered for a user. On the other hand, a viewer might prefer to avoid all commercials, and not get the benefit of a subsidy. The service provider performs the economically efficient function of delivering optimized, substituted commercials for the almost random commercials which flood the commercial broadcast networks, and thus can accrue greater profits, even after paying content providers a reasonable fee. An advertiser, by selecting a particular audience, may pay less than it would otherwise pay to a broadcaster. The content providers may also charge more for the privilege of use of their works.

As stated above, the content may be copy protected by the use of encryption and/or lockout mechanisms. Thus, by providing an alternative to an analog VCR, a full end-to-end encrypted signal may be provided, such as that proposed for the IEEE-1394 copy protection scheme. Because enhanced recording capabilities are provided to the consumer, the acceptance will be high. Because of the encryption, lack of portability and continued royalty accounting, content provider acceptance will also likely be high.

The user interface concepts according to the present invention are easily applied to other special purpose programmable devices, and also to general purpose programmable devices wherein the programming paradigm is event-driven, as well as other programming systems. It should also be noted that it is within the scope of the present invention to provide an improved interface and programming environment for all types of programmable devices, and in this regard, the present invention incorporates adaptive features which optimize the programming environment for both the level of the user and the task to be programmed.

In optimizing the interface, four elements are particularly important: the input device, the display format, the sequence of the programming operation, and the ability of the device to properly interpret the input as the desired program sequence.

The present invention proceeds from an understanding that an absence of user frustration with respect to a programmable consumer or industrial device or interface, may be particularly important with respect to achieving the maximum potential functionality thereof. The interface must be designed to minimize the user's frustration level. This can be accomplished by clearly furnishing the possible choices, presenting the data in a logical sequence, and leading the user through the steps necessary to program the device.

When applied to other than audiovisual and/or multimedia application, the pattern recognition function may be used to control the execution of a program or selectively control execution of portions of the software. For example, in a programmable temperature controller application, a sensor or sensor array could be arranged to detect a “door opening”. On the occurrence of the door opening, the system would recognize this pattern, i.e. a mass of air at a different temperature entering the environment from a single location, or a loss of climate controlled air through a single location. In either event, the system would take appropriate action, including: halt of normal climate control and impose a delay until the door is closed; after closure, set a time constant for maintenance of a steady state of the replaced air with the climate controlled air; based on the actual climatic condition after assimilation, or a predicted climatic condition after assimilation, begin a climate compensation control; optionally, during the door opening, control a pressure or flow of air to counterbalance the normal flow through the door, by using a fan or other device. The climate may differ in temperature, humidity, pollutants, or the like, and appropriate sensors may be employed.

The present invention also allows a dynamic user preference profile determination based on explicit or implicit desires, e.g., moods, which assist in processing data to make decisions which conform to the user preference at a given point in time. For example, voice patterns, skin temperature, heat pulse rate, external context, skin resistance (galvanic skin response), blood pressure, stress, as determined by EMG, EEG or other known methods, spontaneous motor activity or twitching, may be detected in order to determine or infer a user mood, which may be used as a dynamic influence on the user preference. These dynamic influences are preferably stored separately from static influences of the preferences, so that a resultant determined preference includes a dynamic influence based on a determined mood or other temporally varying factor and a static influence associated with the user.

When a group of people are using the system simultaneously, the system must make a determination of a composite preference of the group. In this case, the preferences of the individuals of the group, if known, may be correlated to produce an acceptable compromise. Where individual preferences are not a priori known, individual or group “interviews” may be initially conducted to assist in determining the best composite group preference.

It is therefore an object according to the present invention to provide a radio receiver or video receiver device, having a plurality of different available program sources, determining a program preference for one or more individuals subject to a presented program, comparing the determined program preference and a plurality of different program sources, and selects at least one program based on the comparison.

In formulating a group preference, individual dislikes may be weighted more heavily than likes, so that the resulting selection is tolerable by all and preferable to most group members. Thus, instead of a best match to a single preference profile for a single user, a group system provides a most acceptable match for the group. It is noted that this method is preferably used in groups of limited size, where individual preference profiles may be obtained, in circumstances where the group will interact with the device a number of times, and where the subject source program material is the subject of preferences. Where large groups are present, demographic profiles may be employed, rather than individual preferences. Where the device is used a small number of times by the group or members thereof, the training time may be very significant and weigh against automation of selection. Where the source material has little variety, or is not the subject of strong preferences, the predictive power of the device as to a desired selection is limited.

The present invention provides a system and method for making use of the available broadcast media forms for improving an efficiency of matching commercial information to the desires and interests of a recipient, improving a cost effectiveness for advertisers, improving a perceived quality of commercial information received by recipients and increasing profits and reducing required information transmittal by publishers and media distribution entities.

This improved advertising efficiency is accomplished by providing a system for collating a constant or underlying published content work with a varying, demographically or otherwise optimized commercial information content. This commercial information content therefore need not be predetermined or even known to the publisher of the underlying works, and in fact may be determined on an individual receiver basis. It is also possible to integrate the demographically optimized information within the content. For example, overlays in traditional media, and electronic substitutions or edits in new media, may allow seamless integration. The content alteration need not be only based on commercial information, and therefore the content may vary based on the user or recipient.

U.S. Pat. No. 5,469,206, expressly incorporated herein by reference, relates to a system that automatically correlates user preferences with electronic shopping information to create a customized database for the user.

Therefore, the granularity of demographic marketing may be very fine, on a receiver-by-receiver basis. Further, the accounting for advertisers will be more accurate, with a large sample and high quality information. In fact, in a further embodiment, an interactive medium may be used allowing immediate or real time communication between recipient and advertiser. This communication may involve the Internet, private networks or dial-up connections. Because the commercial messages are particularly directed to recipients, communication with each selected recipient is more valuable to an advertiser and that advertiser is willing to pay more for communication with each selected recipient. Recipients may therefore be selected to receive the highest valued appropriate commercial message(s). Thus, advertisers will tend to pay less and media producers will gain more revenues. Recipients will gain the benefit of selected and appropriate media, and further, may provide feedback for determining their preferences, which will likely correspond with their purchasing habits. Thus, the recipient will benefit by receiving optimized information.

Likewise, a recipient may place a value on receiving certain information, which forms the basis for “pay-per-view” systems. In this case, the recipient's values may also be considered in defining the programming.

This optimization is achieved by providing a device local to the recipient which selectively presents commercial information to the recipient based on characteristics individual to the recipient, which may be input by the recipient, the publisher, the advertiser, and/or learned by the system based on explicit or implicit feedback. The local device either has a local memory for advertising materials, or a telereception link for receiving commercial information for presentation, either on a real time basis or stored for later presentation. In a further embodiment, a user may control the content and/or commercial information received. In this case, the accounting system involves the user's account, and, for example, the recipient may be denied the subsidy from the commercial advertiser, and pay for the privilege of commercial free content.

It is also possible to employ the methods and systems according to the present invention to create a customized publication, which may be delivered physically to the recipient, for example as print media, facsimile transmission, e-mail, R-CD-ROM, floppy disk, or the like, without having a device local to the consumer.

It is noted that this system and method is usable for both real time media, such as television, radio and on-line telecommunication, as well as manually distributed periodicals, such as newspapers, magazines, CD-ROMs, diskettes, etc. Therefore, the system and method according to the present invention includes a set of related systems with varying details of implementation, with the underlying characteristic of optimization of variable material presentation at the recipient level rather than the publisher level.

The system and method according to the present invention preferably includes an accounting system which communicates information relating to receipt of commercial advertising information by a recipient to a central system for determination of actual receipt of information. This feedback system allows verification of receipt and reduces the possibility of fraud or demographic inaccuracies.

The accounting system, for example, may place value on the timeslot, associated content, the demographics of the user, user's associated valuation, competition for placement, past history (number of impressions made to same recipient) and exclusivity.

A preferred embodiment includes a subscription television system having a plurality of received channels. At Least one of these channels is associated with codes to allow determination of content from variable segments. It is also possible to identify these variable segments without these codes, although the preferred system includes use of such codes. These codes also allow simple identification of the content for accounting purposes. Upon detection of a variable segment, a commercial advertisement is selected for presentation to the recipient. This variable segment is selected based on the characteristics of the recipient(s), the history of use of the device by the recipient(s), the context of use, the arrangements made by the commercial information provider(s) for presentation of information, and the availability of information for presentation. Other factors may include the above-mentioned accounting system factors. Typically, the local device will include a store of commercial information, downloaded or otherwise transmitted to the recipient (e.g., a CD-ROM or DVD with MPEG-2 compressed images). A telecommunication link may also be provided to control the process, provide parameters for the presentation or the information itself. This telecommunication link may be provided through the public telephone network, Internet, private network (real or virtual) cable network, or a wireless network, for example. Generally, the underlying work will have a gap of fixed length, so that the commercial information must be selected to fit in this gap. Where the gap is of variable length, such as might occur in live coverage, the commercial information is interrupted or the underlying work buffered and delayed to prevent loss. Thus, the presentation to the user is constructed from pieces, typically at the time of presentation, and may include invariable content, variable content, invariable messages, variable messages, targeted content and/or messages, and hypervariable content. Hypervariable content includes, for example, transition material selected based on the stream of information present, and other presentations which my optionally include useful information which are individualized for the particular recipient or situation.

According to another embodiment, a recording, such as on a videotape, is retained by a recipient which includes proprietary content. This may include a commercial broadcast, a private broadcast, or distributed media. In the case of a commercial broadcast, some or all of the commercial advertising or other time-sensitive information is old and/or stale. Therefore, in operation, this old or time sensitive information is eliminated and substituted with new and/or different information. Thus, the presentation system freshens the presentation, editing and substituting where necessary.

By such a method, content distributed even through private channels may include advertisements, and thus be subsidized by advertisers. The advertisements and other added content are generally more acceptable to the audience because they are appropriately targeted.

For example, where the broadcaster has a high degree of control over the initial broadcast, e.g., pay per view under license, or where the broadcaster may claim substantial continuing rights in the work after recording, the enforcement of a proprietary replay system may be accepted. For example, a work is broadcast as an encrypted digital data stream, with selective decryption at the recipient's receiver, under license from the broadcaster. In this case, a recording system is provided which retains the encryption characteristics, ensuring the integrity of the accounting process. During presentation of the recorded work, commercial information is appropriately presented to the recipient during existing or created gaps, or in an associated output separate from the content presentation. The recipient, as a result, receives the benefit of the original subsidy, or may receive a new subsidy.

Therefore, similar to the known DIVX system, an encrypted media may be mass distributed, which requires authorization for display. Instead, however, of requiring the recipient to pay for the initial and subsequent displays of the content, the player integrates advertising content into the output, which may vary based on the audience, time and past history, as well as other factors discussed herein. Given the interactive and variable nature of the presentation, the user or audience may even veto (“fast forward through”) a particular commercial. In this case, the use may have to account for a fee, or other advertisers may tack up the slack. The veto provides information regarding the desires of the viewer, and may be used to help select future messages to the displayed or presented.

According to another embodiment, a radio transmission/reception system is provided which broadcasts content, an overlay track and variable commercial information. The invariant works are preferably prerecorded music. The overlay track is preferably a “DJ”, who provides information regarding the invariant works, commercial information or news. The commercial information in this instance therefore refers to prerecorded segments. In this instance, the goal is to allow the invariant works to be received by the recipient and presented with improved optimization of the commercial information content and other messages presented at the time of output. Further, this system allows optimization of the presentation of the invariant portions as well, i.e., the commercial information and the program content may be independently selected at the receiver, with appropriate accounting for commercial subsidy. In a mobile receiver, it is preferable to include as a factor in the selection of commercial information a location of the receiver, as might be obtained from a GPS system, cellular location system, intelligent highway system or the like. This would allow geographically appropriate selection of commercial information, and possibly overlay information as well, e.g., traffic reports.

Another embodiment according to the present invention provides a hypertext linked media or multimedia environment, such as HTML/World Wide Web, wherein information transmitted and/or displayed is adaptively selected based on the particular user or the user's receiving system. Thus, various elements may be dynamically substituted during use.

Therefore, it is an object according to the present invention to provide adaptive man-machine interfaces, especially computer graphic user interfaces, which are ergonomically improved to provide an optimized environment. Productivity of computer operators is limited by the time necessary to communicate a desired action through the user interface to the device. To reduce this limitation, most likely user actions are predicted and presented as easily available options. The technologies also extend beyond this core theme in many differing ways, depending on the particular application.

The system also provides an intelligent, adaptive pattern recognition function in order to provide the operator with a small number of high probability choices, which may be complex, without the need for explicit definition of each atomic instruction comprising the desired action. The interface system predicts a desired action based on the user input, a past history of use, and a context of use.

In yet another embodiment, a present mood of a user is determined, either explicitly or implicitly, and the device selects program material that assists in a desired mood transition. The operation of the device may additionally acquire data relating to an individual and the respective moods, desires and characteristics, altering the path provided to alter the mood based on the data relating to the individual. As stated above, in a group setting, a most acceptable path is presented rather than a most desirable path as presented for an individual.

In determining mood, a number of physiologic parameters may be detected. In a training circumstance, these set of parameters are correlated with a temporally associated preference. Thus, when a user inputs a preference into the system as feedback, mood data is also obtained. Invariant preferences may be separated, and analyzed globally, without regard for temporal variations, while varying preferences are linked with information regarding the surrounding circumstances and stored. For example, the preference data may be used to train a neural network, e.g., using backpropagation of errors or other known methods. The inputs to the neural network include available data about surrounding context, such as time, environmental brightness, and persons present; source program choices, which may be raw data, preprocessed data, and abstracted data; explicit user input; and, in this embodiment, mood parameters, which may be physiological or biometric data, voice pattern, or implicit inputs. An example of an implicit input is an observation of a man-machine interaction, such as a video game. The manner in which a person plays a video game or otherwise interacts with a machine may provide valuable data for determining a mood or preference.

According to one embodiment of the invention, the image is preprocessed to decompose the image into object-elements with various object-elements undergoing separate further processing. For example, certain backgrounds may be aesthetically modeled using simple fractal equations. While, in such circumstances the results may be inaccurate in an absolute sense, they may be adequate in a performance sense. Faces, on the other hand, have common and variable elements. Therefore, a facial model may be based on parameters having distinguishing power, such as width between eyes, mouth, shape of ears, and other proportions and dimensions. Thus, along with color and other data, a facial image may be stored as a reference to a facial model with the distinguishing parameters for reconstruction. Such a data processing scheme may produce a superior reconstructed image and allow for later recognition of the face, based on the stored parameters in reference to the model. Likewise, many different elements of an image may be extracted and processed in accordance with specific models to produce differentiating parameters, wherein the data is stored as a reference to the particular model along with the particular data set derived from the image. Such a processing scheme allows efficient image storage along with ease of object recognition, i.e., distinction between objects of the same class. This preprocessing provides a highly asymmetric scheme, with a far greater processing complexity to initially process the image than to subsequently reconstruct or otherwise later employ the data.

By employing a model-based object extraction system, the available bandwidth may be efficiently used, so that objects which fall within the scope of an available model may be identified with a model identification and a series of parameters, and objects not within the scope of a model may be allocated a comparatively greater bandwidth for general image description, e.g., JPEG, MPEG-1/MPEG-2, wavelet, standard fractal image compression (FIC), or other image processing schemes. In a worst case, therefore, the bandwidth required will be only slightly greater than that required for a corresponding standard method, due only to the additional overhead to define data types, as necessary. However, by employing a model based-object decomposition processing system, recognized elements may be described using only a small amount of data and a greater proportion of data used to describe unrecognized elements. Further, the models available may be dynamically updated, so that, as between a communicating transmitted and receiver, retransmission of unrecognized elements will be eliminated as a model is constructed.

Where image processing systems may produce artifacts and errors, an error minimization function may also be provided which compares an original image with a decomposed-recomposed image and produces an error function which allows correction for these errors. This error function may be transmitted with the processed data to allow more faithful reproduction. In a pattern recognition context, the error function may provide useful data relating to the reliability of a pattern correlation, or may provide useful data outside of the model and associated parameters for pattern recognition.

Thus, in the case of an object-extraction model-based processing system, the resulting data stream may be appropriate for both viewing and recognition. Of course, acoustic data may be likewise processed using acoustic models with variable parameters. However, in such a system, information for pattern recognition may be filtered, such as eliminating the error function or noise data. Further, certain types of objects may be ignored, for example, under normal circumstances, clouds in the sky provide little information for pattern recognition and may be removed. In such a system, data intended for viewing or listening will likely contain all objects in the original data stream, with as much original detail as possible given data storage and bandwidth constraints.

An object extraction model based processing system also allows for increased noise rejection, such as over terrestrial broadcast channels. By transmitting a model, the receiving system may interpolate or extrapolate data to fill in for missing data. By extrapolate, it is meant that past data is processed to predict a subsequent condition. By interpolate, it is meant that data presentation is delayed, and missing data may therefore be predicted from both past and subsequent data transmission. Missing portions of images may also be reconstructed from existing portions. This reconstruction process is similar to that described in U.S. Pat. No. 5,247,363, to reconstruct MPEG images; except that where model data is corrupted, the corruption must be identified and the corrupt data eliminated and replaced with predicted data.

It is therefore an object according to the present invention to provide a programmable control, having a status, responsive to an user input and a signal received from a signal source, comprising a controller, for receiving the user input and the signal and producing a control output; a memory for storing data relating to an activity of the user; a data processing system for adaptively predicting a most probable intended action of the user based on the stored data relating to the activity of the user and derived weighing of at least a subset of possible choices, the derivation being based on a history of use, a context of a respective choice and the status of the control; and a user feedback data presenting system comprising an output device for presentation of a variable sequence of programming options to the user, including the most probable intended action of the user, in a plurality of output messages, the output messages differing in available programming options.

The programmable control may be employed for performing an action based on user input and an information content of a signal received from a signal source, wherein the output device includes a display device, further comprising a user controlled direct manipulation-type input device, associated with the display device, having a device output, the device output being the user input; a plant capable of performing the action, being responsive to an actuator signal; and the controller, being for receiving data from the device output of the input device and the signal, and displaying user feedback data on the display device, the logical sequence of the user feedback data including at least one sequence of options sufficient to define an operable control program, and a presentation of additional programming options if the control program is not operable.

The programmable control may further comprise a user input processing system for adaptively determining a viewer preference based on the user input received by the controller; a program material processing system for characterizing the program material based on its content; a correlator for correlating the characterized content of the program material with the determined viewer preference to produce a correlation index; and a processor, selectively processing the program material based on the correlation index, the data processing system receiving an input from the processor.

The programmable control, may also comprise a plurality of stored profiles, a processor for characterizing the user input to produce a characterized user input; and means for comparing the characterized user input with at least one of the plurality of stored profiles to produce a comparison index, wherein the variable sequence of programming options is determined on the basis of the comparison index. The processor for characterizing may perform an algorithm on the signal comprising a transform selected from the group consisting of an Affine transformation, a Fourier transformation, a discrete cosine transformation and a wavelet transformation.

It is a further object according to the present invention to provide a programmable controller for controlling a recording device for recording an analog signal sequentially on a recording medium having a plurality of uniquely identifiable storage locations, further comprising a sequential recording device for recording the analog signal, and a memory for storing, in a directory location on the recording medium which is separate from the storage location of the analog signal, information relating to the signal, processed to selectively retain characterizing information, and an identifier of a storage location on the recording medium in which the analog signal is recorded.

It is another object according to the present invention to provide a control, wherein program material is encrypted, further comprising a decryption system for decrypting the program material if it is selected to produce unencrypted program material and optionally an associated decryption event; a memory for storing data relating to the occurrence of the decryption event; and a central database for storing data relating to the occurrence of the decryption event in association with data relating to the viewer.

It is still another object according to the present invention to provide a control wherein the user input processing system monitors a pattern of user activity and predicts a viewer preference; the program material processing system comprising a processor for preprocessing the program material to produce a reduced data flow information signal substantially retaining information relating to the abstract information content of the program material and selectively eliminating data not relating to the abstract information content of the program material and for characterizing the information signal based on the abstract information content; and a comparing system for determining if the correlation index is indicative of a probable high correlation between the characterization of the information signal and the viewer preference and causing the stored program material to be processed by the processing means based on the determination. The system according to this aspect of the present invention preferably comprises an image program material storage and retrieval system.

The present invention further provides a control further comprising a memory for storing a characterization of the program material; an input for receiving a feedback signal from the viewer indicating a degree of agreement with the correlation index determination, wherein the feedback signal and the stored characterization are used by the viewer preference predicting means to predict a new viewer preference.

According to another aspect of the invention, it is an object to provide an image information retrieval apparatus, comprising a memory for storing compressed data representing a plurality of images; a data storage system for retrieving compressed data representing at least one of the plurality of images and having an output; a memory for storing characterization data representing a plurality of image types, having an output; and an image processor, receiving as inputs the outputs from the data storage system and the characterization data memory, and producing a signal corresponding to a relation between at least one of the plurality of images of the compressed data and at least one of the image types of the characterization data.

It is a still further aspect of the present invention to provide a video interface device for a user comprising a data transmission system for simultaneously transmitting data representing a plurality of programs; a selector for selecting at least one of the plurality of programs, being responsive to an input; a program database containing information relating to the plurality of programs, having an output; a graphical user interface for defining commands, comprising (a) an image display device having at least two dimensions of display, being for providing visual image feedback; and (b) a multidimensional input device having at least two dimensions of operability, adapted to correspond to the two dimensions of the display device, and having an output, so that the user may cause the input device to produce a corresponding change in an image of the display device by translating an indicator segment of the display in the at least two dimensions of display, based on the visual feedback received from the display device, the indicator segment being moved to a translated location of the display device corresponding to a user command; and a controller for controlling the graphical user interface and for producing the input of the selector, receiving as a control the output of the multidimensional input device, the controller receiving the output of the program database and presenting information relating to at least one of the plurality of programs on the display device associated with a command, the command being interpreted by the control means as the user command to produce the input of the selector to select the at least one of the plurality of programs associated with the command.

Another object of the present invention is to provide an apparatus, receiving as an input from a human user having a user characteristic, comprising an input device, producing an input signal from the human user input; a display for displaying information relating to the input from the user and feedback on a current state of the apparatus, having an alterable image type; an input processor for extracting an input instruction relating to a desired change in a state of the apparatus from the input signal; a detector for detecting one or more temporal-spatial user characteristics of the input signal, independent of the input instruction, selected from the group consisting of a velocity component, an efficiency of input, an accuracy of input, an interruption of input and a high frequency component of input; a memory for storing data related to the user characteristics; and a controller for altering the image type based on the user characteristics. The controller may alter the image type based on an output of the detector and the stored data so that the display displays an image type which corresponds to the detected user characteristics. The controller may further be for controlling the causation of an action on the occurrence of an event, further comprising a control for receiving the input instruction and storing a program instruction associated with the input instruction, the control having a memory sufficient for storing program instructions to perform an action on the occurrence of an event; and a monitor for monitoring an environment of the apparatus to determine the occurrence of the event, and causing the performance of the action on the occurrence of the event. The controller may also alters the image type based on an output of the detector and the stored data so that the display means displays an image type which corresponds to the detected user characteristics.

It is another object of the present invention to provide an adaptive programmable apparatus having a plurality of states, being programmable by a programmer and operating in an environment in which a plurality of possible events occur, each of the events being associated with different data, comprising an data input for receiving data; an programmer input, producing an input signal from the programmer; a memory for storing data relating to the data input or the input signal; a feedback device for adaptively providing information relating to the input signal and a current status of the apparatus to the programmer, based on the data input or the programmer input, the stored data, and derived weighing of at least a subset of possible choices, the derived weighing being based on a history of use, a context of a respective choice and the current status of the apparatus; a memory for storing programming data associated with the input signal; and a processor, having a control output, for controlling the response of the apparatus relating to the detection of the input signal or the data in accordance with the stored programming data, the processor: (a) processing the at least one of the input signal or the data to reduce an amount of information while substantially retaining an abstract portion of the information; (b) storing a quantity of the abstracted information; (c) processing the abstract portion of the information in conjunction with the stored quantity of abstracted information; and (d) providing the control output based on the processed abstract portion of the information and the stored programming data. The apparatus may further comprise an input for receiving a programming preference from the programmer indicating a plurality of possible desired events; the processor further including a correlator for correlating the programming preference with the data based on an adaptive algorithm and for determining a likelihood of occurrence of at least one of the desired events, producing, the control output. The apparatus may further comprise an input for receiving feedback from the programmer indicating a concurrence with the control output of the processor, and modifying the response control based on the received feedback to increase a likelihood of concurrence. The apparatus may still further verify the programming data to ensure that the programming data comprise a complete and consistent set of instructions; and include a feedback system for interactively modifying the programming data. The apparatus may also comprise a chronological database and an accessing system for accessing the chronological database on the basis of the programming data stored in the memory.

It is also an object according to the present invention to provide an apparatus comprising an input for receiving a programming preference from the programmer indicating a plurality of possible desired events; and a correlator for correlating the programming preference with the data based on an adaptive algorithm and for determining a likelihood of occurrence of at least one of the desired events, producing the output, the output being associated with the initiation of the the response.

The present invention also provides as an object an apparatus comprising an input for receiving feedback from the programmer indicating a concurrence with the output of the correlator, and modifying the algorithm based on the received feedback, the feedback device comprising a display and the input device is remote from the display, and providing a direct manipulation of display information of the display.

According to an aspect of the present invention, a processor of the programmable apparatus verifies the program instructions to ensure that the program instructions are valid and executable by the processor; an output for providing an option, selectable by the programmer input for changing an instruction stored by the processor, such that the apparatus enters a state wherein a new instruction may be input to substitute for the instruction, wherein the processor verifies the instructions such that the instructions are valid; and wherein the feedback device further presents information requesting confirmation from the programmer of the instructions associated with the input signal. The apparatus may further comprise a chronological database and an accessing system for accessing the chronological database on the basis of the program instructions stored in the memory.

The processor of the programmable apparatus may receive information from the input signal and/or from the data input; and may further comprise an input signal memory for storing at least a portion of the input signal or the data, a profile generator for selectively generating a profile of the input signal or the data, and an input signal profile memory for storing the profile of the input signal or the data separately from the input signal or the data in the input signal memory. The programmable apparatus may further comprise a processor for comparing the input signal or the data with the stored profile of the input signal or the data to determine the occurrence of an event, and the data optionally comprises image data and the processor for comparing performs image analysis. The image data may comprise data having three associated dimensions obtained by a method selected from the group consisting of synthesizing a three dimensional representation based on a machine based model derived from two dimensional image data, synthesizing a three dimensional representation derived from a time series of pixel images, and synthesizing a three dimensional representation based on a image data representing a plurality of parallax views each having at least two dimensions.

A user feedback data presenting device according to the present invention may comprise a display having a plurality of display images, the display images differing in available programming options.

According to another aspect of the present invention, a program material processing system is provided comprising means for storing template data; means for storing the image data; means for generating a plurality of domains from the stored image data, each of the domains representing different portions of the image information; means for creating, from the stored image data, a plurality of addressable mapped ranges corresponding to different subsets of the stored image data, the creating means including means for executing, for each of the mapped ranges, a procedure upon the one of the subsets of the stored image data which corresponds to the mapped range; means for assigning identifiers to corresponding ones of the mapped ranges, each of the identifiers specifying for the corresponding mapped range an address of the corresponding subset of stored image data; means for selecting, for each of the domains, the one of the mapped ranges which most closely corresponds according to predetermined criteria; means for representing at least a portion of the image information as a set of the identifiers of the selected mapped ranges; and means for selecting, from the stored templates, a template which most closely corresponds to the set of identifiers representing the image information. The means for selecting may comprise means for selecting, for each domain, the mapped range which is the most similar, by a method selected from at least one of the group consisting of selecting a minimum Hausdorff distance from the domain, selecting the highest cross-correlation with the domain and selecting the lowest mean square error of the difference between the mapped range and the domain. The means for selecting may also comprise, for each domain, the mapped range with the minimum modified Hausdorff distance calculated as D[db,mrb]+D[1-db,1-mrb], where D is a distance calculated between a pair of sets of data each representative of an image, db is a domain, mrb is a mapped range, 1-db is the inverse of a domain, and 1-mrb is an inverse of a mapped range. The means for representing may further comprise means for determining a feature of interest of the image data, selecting a mapped range corresponding to the feature of interest, storing the identifiers of the selected mapped range, selecting a further mapped range corresponding to a portion of image data having a predetermined relationship to the feature of interest and storing the identifiers of the further mapped range.

According to an embodiment of the present invention, the image data comprises data having three associated dimensions obtained by a method selected from the group consisting of synthesizing a three dimensional representation based on a machine based prediction derived from two dimensional image data, synthesizing a three dimensional representation derived from a time series of pixel images, and synthesizing a three dimensional representation based on a image data representing a plurality of parallax views having at least two dimensions.

It is therefore an object of the present invention to provide a programmable apparatus for receiving instructions from a programmer and causing an action to occur on the happening of an event, comprising an input device, producing an input instruction signal; a control means for receiving the input instruction signal, and storing a program instruction associated with the input instruction signal, the control means storing sufficient program instructions to perform an action on the occurrence of an event, the control means monitoring a status of the apparatus to determine the occurrence of various events, comparing the determined events with the program instructions, and performing the action on the occurrence of the event; a display means for interactively displaying information related to the instructions to be received, and responsive thereto, controlled by the control means, so that the programmer is presented with feedback on a current state of the apparatus and the program instruction; wherein the control means further comprises means for detecting one or more characteristics of the input instruction signal independent of the program instruction selected from the group consisting of a velocity component, an efficiency of input, an accuracy of input, an interruption of input, a high frequency component of input and a past history of input by the programmer, whereby when the control means detects a characteristic indicating that the display means is displaying information in a suboptimal fashion, the control means controls the display means to display information in a more optimal fashion.

It is also an object of the present invention to provide a programmable apparatus for receiving instructions from a programmer and causing an action to occur on the happening of an event, comprising an input device, producing an input instruction signal; a control means for receiving the input instruction signal, and storing a program instruction associated with the input instruction signal, the control means storing sufficient program instructions to perform an action on the occurrence of an event, the control means monitoring a status of the apparatus to determine the occurrence of various events, comparing the determined events with the program instructions, and performing the action on the occurrence of the event; a display means for interactively displaying information related to the instructions to be received, and responsive thereto, controlled by the control means, so that the programmer is presented with feedback on a current state of, the apparatus and the program instruction; wherein the control means further comprises means for detecting a need by the programmer for more detailed information displayed on the display means, by detecting one or more characteristics of the input instruction signal independent of the program instruction selected from the group consisting of a velocity component, an efficiency of input, an accuracy of input, an interruption of input, a high frequency component of input and a past history of input by the programmer, whereby when the control means detects a characteristic indicating that the display means is insufficiently detailed information, the control means controls the display means to display more detailed information.

It is a further object of the present invention to provide a programmable apparatus having a data input, the apparatus receiving instructions from a programmer and causing an action to occur on the receipt of data indicating an event, comprising an input device, producing an input instruction signal; a control means for receiving the input instruction signal, and storing a program instruction associated with the input instruction signal, the control means storing sufficient program instructions to perform an action on the receipt of data indicating an event, the control means monitoring the data input; a display means for interactively displaying information related to the instructions to be received, and responsive thereto, controlled by the control means, so that the programmer is presented with feedback on a current state of the apparatus and the program instruction; wherein the control means receives a programming preference indicating a desired event from the input device which does not unambiguously define the event, and the control means monitors the data and causes the occurrence of the action when a correlation between the programming preference and the monitored data is above a predetermined threshold, indicating a likely occurrence of the desired event. It is also object of the present invention to provide the programmable aforementioned apparatus, wherein the input device is remote from the display means, and provides a direct manipulation of display information of the display means, further comprising means for verifying the program instructions so that the program instructions are executable by the control means. The control means may further comprise a calendar or other chronological database.

Another object of the present invention provides a programmable information storage apparatus having a data input, for receiving data to be stored, the apparatus receiving instructions from a programmer and causing an action to occur on the receipt of data indicating an event, comprising means for storing data from the data input; an input device, producing an input instruction signal; a control means for receiving the input instruction signal, and storing a program instruction associated with the input instruction signal, the control means storing sufficient program instructions to perform an action on the receipt of data from the data input indicating an event, the control means monitoring the data input to determine the occurrence of various events, comparing the determined events with the program instructions, and performing for storing the data the action on the occurrence of the event; wherein the control means receives identifying data from at least one of the input device and the data input, the identifying data being stored separately from the input data on a storage medium. The programmable information storage apparatus may also include means for reading the identifying data stored separately on the storage medium, and may also receive as an input the identifying data.

It is also an object of the present invention to provide a programmable apparatus, wherein the control means provides an option, selectable by the input means in conjunction with the display means, for changing an input program instruction prior to execution by the control means, so that the apparatus enters a state wherein a new program instruction may be input to substitute for the changed input step, wherein the control means verifies the program instructions so that the program instructions are executable by the control means.

It is still another object of the present invention to provide a programmable apparatus, wherein the control means further causes the display means to display a confirmation screen after the program instructions are input, so that the programmer may confirm the program instructions.

Another object of the present invention is to provide a programmable information storage apparatus, wherein the control means further comprises means for recognizing character data present in a data stream of the input data, the identifying data comprising the recognized character data.

It is a still further object of the present invention to provide a video tape recording apparatus, comprising a video signal receiving device, a recording device for recording the video signal, wherein the control analyzes the video signal for the presence of a symbol, and recognizes the symbol as one of a group of recognized symbols, and the control stores the recognized symbol separately from the video signal.

Another object of the present invention is to provide a recording device for recording an analog signal sequentially on a recording medium, comprising means for characterizing the analog signal, wherein data representing the characterization and a location of the analog signal on the recording medium are stored in a directory location on the recording medium separately from the analog signal.

It is a further object of the present invention to provide an interface for a programmable control for input of a program for a controller to execute, which performs an action based on an external signal, comprising an input device, a controller for receiving data from the input device and from an external stimulus, a plant being controlled by the controller based on an input from the input device and the external stimulus, and a display device being controlled by the controller, for providing visual feedback to a user operating the input device, wherein a predetermined logical sequence of programming options is presented to the user on the display device, in a plurality of display screens, each of the display screens differing in available programming choices; the logical sequence including a correct sequence of choices to set an operable control program, so that no necessary steps are omitted; the external stimulus comprises a timing device, and the display comprises a display option for programming the plant to perform an action at a time which is input through the input device as a relative position on the display device, the relative position including a means for displaying an absolute time entry and means for displaying a relative time entry, the display also comprising a display option means for performing an action at a time; the control comprises means for presenting the user, on the display device, with a most probable action, which may be selected by the user through activation of the input device without entering data into the controller through the input device relating to both the action and the event; the display also comprising means for indicating completion of entry of a programming step, which means indicates to the user an indication that the programming step is not completed if information necessary for execution of the step is not available to the controller; and the controller being capable of controlling the display device to present information to the user relating to the use of the apparatus if necessary for use of the device by the user.

Another object of the present invention provides a system for presenting a program to a viewer, comprising a source of program material; means for determining a viewer preference, the viewer preference optionally being context sensitive; means for receiving the program material from the source; means for characterizing the program material based on its content; means for correlating the characterized content of the program material with the determined viewer preference to produce a correlation index; and means for presenting the program material to the viewer, if the correlation index indicates a probable high correlation between the characterization of the program material and the viewer preference.

Another object of the present invention is to provide a system for presenting a program to a viewer, comprising a source of program material; means for determining a viewer preference; means for receiving the program material from the source; means for storing the program material; means for preprocessing the program material to produce a reduced data flow information signal retaining information relating to a character of the program material and eliminating data not necessary to characterize the program material; means for characterizing the information signal based on its content; means for correlating the characterized content of the information signal with the determined viewer preference to produce a correlation index; and means for presenting the stored program material to the viewer, if the correlation index indicates a probable high correlation between the characterization of the information signal and the viewer preference. The system may also include a means for storing the information signal, wherein the characterizing means characterizes the stored information signal, and also a memory for storing the program material while the characterizing means produces characterized content and the correlating means produces the correlation index.

Still another object of the present invention is to provide a system, wherein the program material is encrypted, further comprising means for decrypting the program material to produce a decryption event; and means for charging an account of the viewer based on the occurrence of a decryption event. Thus, a decryption processor and an accounting database are provided for these purposes.

Another object of the present invention is to allow the means for characterizing the program material to operate without causing a decryption event. Thus, the data stream may include characterization data specifically suitable for processing by a characterizing system, or the decryption processor may be provided with multiple levels of functionality, or both. Further, the system may comprise a memory for storing the program material while the characterizing means produces characterized content and the correlating means produces the correlation index. The characterizing means may also characterize the program material stored in memory, and the program material stored in memory may be compressed.

Another object of the present invention is to provide a controller for controlling a plant, having a sensor for sensing an external event and producing a sensor signal, an actuator, responsive to an actuator signal, for influencing the external event, and a control means for receiving the sensor signal and producing an actuator signal, comprising means for inputting a program; means for storing the program; means for characterizing the sensor signal to produce a characterized signal; and means for comparing the characterized signal with a pattern stored in a memory to produce a comparison index, wherein the actuator signal is produced on the basis of the comparison index and the program, wherein the characterization comprises an Affine transformation of the sensor signal. The characterization may comprise one or more transformation selected from the group consisting of an Affine transformation, a Fourier transformation, a Gabor transformation, and a wavelet transformation.

It is another object of the present invention to provide a method for automatically recognizing digital image data consisting of image information, the method comprising the steps performed by a data processor of storing a plurality of templates; storing the image data in the data processor; generating a plurality of addressable domains from the stored image data, each of the domains representing a portion of the image information; creating, from the stored image data, a plurality of addressable mapped ranges corresponding to different subsets of the stored image data, the creating step including the substep of (a) executing, for each of the mapped ranges, a corresponding procedure upon the one of the subsets of the stored image data which corresponds to the mapped ranges; (b) assigning identifiers to corresponding ones of the mapped ranges, each of the identifiers specifying for the corresponding mapped range a procedure and a address of the corresponding subset of the stored image data; (c) optionally subjecting a domain to a transform selected from the group consisting of a predetermined rotation, an inversion, a predetermined scaling, and a predetermined preprocessing in the time, frequency, and/or wavelet domain; (d) selecting, for each of the domains or transformed domains, the one of the mapped ranges which most closely corresponds according to predetermined criteria; (e) representing the image information as a set of the identifiers of the selected mapped ranges; and (f) selecting, from the stored templates, a template which most closely corresponds to the set of identifiers representing the image information. The step of selecting the mapped ranges may also include the substep of selecting, for each domain, a most closely corresponding one of the mapped ranges.

It is another object of the present invention to provide a method wherein the step of selecting the most closely corresponding one of the mapped ranges includes the step of selecting, for each domain, the mapped range which is the most similar, by a method selected from one or more of the group consisting of selecting minimum Hausdorff distance from the domain, selecting the highest cross-correlation with the domain, selecting the highest fuzzy correlation with the domain and selecting the minimum mean square error with the domain.

Another object of the present invention provides a method wherein the step of selecting the most closely corresponding one of mapped ranges includes the step of selecting, for each domain, the mapped range with the minimum modified Hausdorff distance calculated as D[db,mrb]+D[1-db,1-mrb], where D is a distance calculated between a pair of sets of data each representative of an image, db is a domain, mrb is a mapped range, 1-db is the inverse of a domain, and 1-mrb is an inverse of a mapped range.

Another object of the present invention provides a method wherein the digital image data consists of a plurality of pixels each having one of a plurality of associated color map values, further comprising the steps of optionally transforming the color map values of the pixels of each domain by a function including at least one scaling function for each axis of the color map, each of which may be the same or different, and selected to maximize the correspondence between the domains and ranges to which they are to be matched: selecting, for each of the domains, the one of the mapped ranges having color map pixel values which most closely correspond to the color map pixel values of the domain according to a predetermined criteria, wherein the step of representing the image color map information includes the substep of representing the image color map information as a set of values each including an identifier of the selected mapped range and the scaling functions; and selecting a most closely corresponding stored template, based on the identifier of the color map mapped range, the scaling functions and the set of identifiers representing the image information. The first criteria may comprise minimizing the Hausdorff distance between each domain and the selected range.

Another object of the present invention is to provide a method further comprising the steps of storing delayed image data, which represents an image of a moving object differing in time from the image data in the data processor; generating a plurality of addressable further domains from the stored delayed image data, each of the further domains representing a portion of the delayed image information, and corresponding to a domain; creating, from the stored delayed image data, a plurality of addressable mapped ranges corresponding to different subsets of the stored delayed image data; matching the further domain and the domain by subjecting a further domain to one or both of a corresponding transform selected from the group consisting of a null transform, a rotation, an inversion, a scaling, a translation and a frequency domain preprocessing, which corresponds to a transform applied to a corresponding domain, and a noncorresponding transform selected from the group consisting of a rotation, an inversion, a scaling, a translation and a frequency domain preprocessing, which does not correspond to a transform applied to a corresponding domain; computing a motion vector between one of the domain and the further domain, or the set of identifiers representing the image information and the set of identifiers representing the delayed image information, and storing the motion vector; compensating the further domain with the motion vector and computing a difference between the compensated further domain and the domain; selecting, for each of the delayed domains, the one of the mapped ranges which most closely corresponds according to predetermined criteria; representing the difference between the compensated further domain and the domain as a set of difference identifiers of a set of selected mapping ranges and an associated motion vector and representing the further domain as a set of identifiers of the selected mapping ranges; determining a complexity of the difference based on a density of representation; and when the difference has a complexity below a predetermined threshold, selecting, from the stored templates, a template which most closely corresponds to the set of identifiers of the image data and the set of identifiers of the delayed image data.

Another object of the present invention provides an apparatus for automatically recognizing digital image data consisting of image information, comprising means for storing template data; means for storing the image data; means for generating a plurality of addressable domains from the stored image data, each of the domains representing a different portion of the image information; means for creating, from the stored image data, a plurality of addressable mapped ranges corresponding to different subsets of the stored image data, the creating means including means for executing, for each of the mapped ranges, a procedure upon the one of the subsets of the stored image data which corresponds to the mapped range; means for assigning identifiers to corresponding ones of the mapped ranges, each of the identifiers specifying for the corresponding mapped range an address of the corresponding subset of stored image data; means for selecting, for each of the domains, the one of the mapped ranges which most closely corresponds according to predetermined criteria; means for representing the image information as a set of the identifiers of the selected mapped ranges; and means for selecting, from the stored templates, a template which most closely corresponds to the set of identifiers representing the image information.

It is also an object of the present invention to provide a method and system for processing broadcast material having a first portion and a second portion, wherein the first portion comprises an content segment and the second portion comprises a commercial segment, in order to allow alteration in the presentation of commercial segments, based on the recipient, commercial sponsor, and content provider, while providing means for accounting for the entire broadcast.

Another object of an embodiment of the present invention provides an apparatus comprising a user interface, receiving a control input and a user attribute from the user; a memory system, storing the control input and user attribute; an input for receiving content data; means for storing data describing elements of the content data; means for presenting information to the user relating to the content data, the information being for assisting the user in defining a control input, the information being based on the stored user attribute and the data describing elements of the content data; and means for processing elements of the content data in dependence on the control input, having an output. This apparatus according to this embodiment may be further defined as a terminal used by users of a television program delivery system for suggesting programs to users, wherein the user interface comprises means for gathering the user specific data to be used in selecting programs; the memory system comprises means, connected to the gathering means, for storing the user specific data; the input for receiving data describing elements of the content data comprises means for receiving the program control information containing the program description data; and the processing means comprises program selection means, operably connected to the storing means and the receiving means, for selecting one or more programs using a user's programming preferences and the program control information. In this case, the program selection means may comprise a processor, wherein the user programming preferences are generated from the user specific data; and means, operably connected to the program selection means, for suggesting the selected programs to the user. The apparatus processing means selectively may records the content data based on the output of the processing means. Further, the presenting means presents information to the user in a menu format. The presenting means may comprises means for matching the user attribute to content data.

The data describing elements of an associated data stream may, for example, comprise a program guide generated remotely from the apparatus and transmitted in electronically accessible form; data defined by a human input, and/or data defined by an automated analysis of the content data.

Acording to another embodiment, the present invention comprises a method, comprising the steps of receiving data describing an user attribute; receiving a content data stream, and extracting from the content data stream information describing a plurality of program options; and processing the data describing a user attribute and the information describing a plurality of program options to determine a likely user preference; selectively processing a program option based on the likely user preference. The method may be embodied in a terminal for a television program delivery system for suggesting programs to users for display on a television using program control information and user specific data. In that case, the step of receiving data describing an user attribute may comprise gathering user specific data to be used in selecting programs, and storing the gathered user specific data; the step of receiving a content data stream, may comprise receiving both programs and program control information for selecting programs as the information describing a plurality of program options; the selectively processing step may comprise selecting one or more programs using a user's programming preferences and the received program control information, wherein the user programming preferences are generated from the user specific data; and the method further including the step of presenting the program or information describing a program option for the selected programs to the user.

The user attribute may comprise a semantic description of a preference, or some other type of description, for example a personal profile, a mood, a genre, an image represnting or relating to a scene, a demographic profile, a past history of use by the user, a preference against certain types of media, or the like. In the case of a semantic preference, the data processing step may comprise determining a semantic relationship of the user preference to the information describing a plurality of program options. The program options may, for example, be transmitted as an electronic program guide, the information being in-band with the content (being transmitted on the same channel), on a separate channel or otherwise out of band, through a separate communications network, e.g., the Internet, dial-up network, or other streaming or packet based communications system, or by physical transfer of a computer-readable storage medium, such as a CD-ROM or floppy disk. The electronic program guide may include not only semantic or human-readable information, but also other types of metadata relating to or describing the program content.

In a further embodiment of the present invention, it is an object to provide a device for identifying a program in response to user preference data and program control information concerning available programs, comprising means for gathering the user preference data; means, connected to the gathering means, for storing the gathered user preference data; means for accessing the program control information; and means, connected to the storing means and accessing means, for identifying one or more programs based on a correspondence between a user's programming preferences and the program control information. For example, the ÿÿ901t0b0s10.00v1P identifying means identifies a plurality of programs, a sequence of identifications transmitted to the user being based on a degree of correspondence between a user's programming preferences and the respective program control information of the identified program. The device my selectively record or display the program, or identify the program for tile user, who may then define the appropriate action by the device. Therefore, a user may, instead of defining “like” preferences, may define “dislike” preference, which are then used to avoid or filter certain content. Thus, this feature may be used for censoring or parental screening, or merely to avoid unwanted content. Thus, the device comprises a user interface adapted to allow interaction between the user and the device for response to one or more of the identified programs. The device also preferably comprises means for gathering the user specific data comprises means for monitoring a response of the user to identified programs.

It is a further object of the invention to provide a device which serves as a set top terminal used by users of a television program delivery system for suggesting programs to users using program control information containing scheduled program description data, wherein the means for gathering the user preference data comprising means for gathering program watched data; the means, connected to the gathering means, for storing the gathered user preference data comprising means, connected to the gathering means, for storing the program watched data; the means for accessing the program control information comprising means for receiving the program control information comprising the scheduled program description data; the means, connected to the storing means and accessing means, for identifying one or more programs based on a correspondence between a user's programming preferences and the program control information, being for selecting at least one program for suggestion to the viewer, comprising: means for transforming the program watched data into preferred program indicators, wherein a program indicator comprises a program category with each program category having a weighted value; means for comparing the preferred program indicators with the scheduled program description data, wherein each scheduled program is assigned a weighted value based on at least one associated program category; means for prioritizing the scheduled programs from highest weighted value programs to lowest weighted value programs; means for indicating one or more programs meeting a predetermined weight threshold, wherein all other programs are excluded from program suggestion; and means, operably connected to the program selection means, for displaying for suggestion the selected programs to the user.

It is a further aspect of the invention to provide device a device comprising: a data selector, for selecting a program from a data stream; an encoder, for encoding programs in a digitally compressed format; a mass storage system, for storing and retrieving encoded programs; a decoder, for decompressing the retrieved encoded programs; and an output, for outputting the decompressed programs.

Therefore, the present invention provides a system and method for making use of the available broadcast media forms for improving an efficiency of matching commercial information to the desires and interests of a recipient, improving a cost effectiveness for advertisers, improving a perceived quality of commercial information received by recipients and increasing profits and reducing required information transmittal by publishers and media distribution entities.

This improved advertising efficiency is accomplished by providing a system for collating a constant or underlying published content work with a varying, demographically or otherwise optimized commercial information content. This commercial information content therefore need not be predetermined or even known to the publisher of the underlying works, and in fact may be determined on an individual receiver basis. It is also possible to integrate the demographically optimized information within the content. For example, overlays in traditional media, and electronic substitutions or edits in new media, may allows seamless integration. The content alteration need not be only based on commercial information, and therefore the content may vary based on the user or recipient.

The technologies emphasize adaptive pattern recognition of both the user input and data, with possible use of advanced signal processing and neural networks. These systems may be shared between the interface and operational systems, and therefore a controller for a complex system may make use of the intrinsic processing power available, rather than requiring additional computing resources, although this unification is not required. In fact, while hardware efficiency dictates that near term commercial embodiments employ common hardware for the interface system and the operational system, future designs may successfully separate the interface system from the operational system, allowing portability and efficient application of a single interface system for a number of operational systems.

The adaptive nature of the technologies derive from an understanding that people learn most efficiently through the interactive experiences of doing, thinking, and knowing. Users change in both efficiency and strategy over time. To promote ease-of-use, efficiency, and lack of frustration of the user, the interface of the device is intuitive and self explanatory, providing perceptual feedback to assist the operator in communicating with the interface, which in turn allows the operational system to identify of a desired operation. Another important aspect of man-machine interaction is that there is a learning curve, which dictates that devices which are especially easy to master become frustratingly elemental after continued use, while devices which have complex functionality with many options are difficult to master and may be initially rejected, or used only at the simplest levels. The present technologies address these issues by determining the most likely instructions of the operator, and presenting these as easily available choices, by analyzing the past history data and by detecting the “sophistication” of the user in performing a function, based on all information available to it. The context of use is also a factor in many systems. The interface seeks to optimize the interface adaptively and immediatel:in order to balance and optimize both quantitative and qualitative factors. This functionality may greatly enhance the quality of interaction between man and machine, allowing a higher degree of overall system sophistication to be tolerated.

The interface system analyzes data from the user, which may be both the selections made by the user in context, as well as the efficiency by which the user achieves the selection. Thus, information concerning both the endpoints and path are considered and analyzed by the human user interface system.

The interface may be advantageously applied to an operational system which has a plurality of functions, certain of which are unnecessary or are rarely used in various contexts, while others are used with greater frequency. In such systems, the application of functionality may be predictable. Therefore, the present technologies provide an optimized interface system which, upon recognizing a context, dynamically reconfigures the availability or ease of availability of functions and allows various functional subsets to be used through “shortcuts”. The interface presentation will therefore vary over time, use and the particular user.

The advantages to be gained by using an intelligent data analysis interface for facilitating user control and operation of the system are more than merely reducing the average number of selections or time to access a given function. Rather, advantages also accrue from providing a means for access and availability of functions not necessarily previously existing or known to the user, improving the capabilities and perceived quality of the product.

Further improvements over prior interfaces are also possible due to the availability of pattern recognition functionality as a part of the interface system. In those cases where the pattern recognition functions are applied to large amounts of data or complex data sets, in order to provide a sufficient advantage and acceptable response time, powerful computational resources, such as powerful RISC processors, advanced DSPs or neural network processors are made available to the interface system. On the other hand, where the data is simple or of limited scope, aspects of the technology may be easily implemented as added software-based functionality in existing products having limited computational resources.

The application of these technologies to multimedia data processing systems provides a new model for performing image pattern recognition and for the programming of applications including such data. The ability of the interface to perform abstractions and make decisions regarding a closeness of presented data to selection criteria makes the interface suitable for use in a programmable control, i.e., determining the existence of certain conditions and taking certain actions on the occurrence of detected events. Such advanced technologies might be especially valuable for disabled users.

In a multimedia environment, it may be desirable for a user to perform an operation on a multimedia data event. Past systems have required explicit indexing or identification of images and events. The present technologies, however, allow an image, diagrammatic, abstract or linguistic description of the desired event to be acquired by the interface system from the user and applied to identify or predict the multimedia event(s) desired, without requiring a separate manual indexing or classification effort. These technologies may also be applied to single media data.

e interface system analyzes data from many different sources for its operation. Data may be stored or present in a dynamic data stream. Thus, in a multimedia system, there may be a real-time video feed, a stored event database, as well as an exemplar or model database. Further, since the device is adaptive, information relating to past experience of the interface, both with respect to exposure to data streams and user interaction, is also stored.

This data analysis aspect of the interface system may be substantially processor intensive, especially where the data includes abstract or linguistic concepts or images to be analyzed. Interfaces which do not relate to the processing of such data may be implemented with simpler hardware. On the other hand, systems which handle complex data types may necessarily include sophisticated processors, adaptable for use by the interface system. A portion of the data analysis may also overlap the functional analysis of the data for the operational system.

Other objects and features of the present invention will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed solely for the purposes of illustration and not as a definition of the limits of the invention, for which reference should be made to the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present invention are shown in the figures in the drawings, in which:

FIG. 1 is a flow chart of the steps required to set a VCR;

FIG. 2 shows a graphical comparison of required and extra keypresses for the prior art and the interface of the present invention;

FIG. 3 graphically shows the differences in seconds between total time for the prior art for each user;

FIG. 4 graphically shows the differences in seconds between total time for the interface of the present invention for each user;

FIG. 5 graphically shows the programming steps for the comparison of the prior art and the interface of the present invention;

FIG. 6 graphically shows comparative statistics by user comparing the prior art and the interface of the present invention;

FIGS. 7 and 8 graphically show the critical steps in programming the prior art and the interface of the present invention;

FIG. 9 graphically shows the number of keypresses made by test participants comparing the prior art and the interface of the present invention;

FIG. 10 graphically shows the comparison of the actual and theoretical number of keypresses necessary for programming the prior art and the interface of the present invention;

FIG. 11 graphically compares the actual and theoretical time necessary for programming the prior art and the interface of the present invention;

FIGS. 12 a and 12 b graphically compares the actual and theoretical time necessary for setting the programs in the prior art and the interface of the present invention;

FIGS. 13 and 14 graphically show the percentage time for the critical steps in programming the prior art and the interface of the present invention;

FIG. 15 is a flow diagram of a predictive user interface of the present invention;

FIG. 16 is a flow diagram of the program input verification system of the present invention;

FIG. 17 is a flow diagram of a predictive user preference aware interface of the present invention;

FIG. 18 is a block diagram of a non-program information feature extraction circuit of the present invention;

FIG. 19 is a diagram of a block of information for a catalog entry of the present invention;

FIG. 20 is a block diagram of a digital information and analog signal reading/recording apparatus;

FIG. 21 is a block diagram of a user level determining system of the present invention;

FIG. 22 is a block diagram of a template-based pattern recognition system of the present invention;

FIG. 23 is a block diagram of a control system of the present invention incorporating a pattern recognition element and an interface;

FIG. 24 is a block diagram of a control system for characterizing and correlating a signal pattern with a stored user preference of the present invention;

FIG. 25 is a block diagram of a multiple video signal input apparatus, with pattern recognition, data compression, data encryption, and a user interface of the present invention;

FIG. 26 is a block diagram of a control system for matching a template with a sensor input, of the present invention;

FIGS. 27, 28 and 29 are flow diagrams of an iterated function system method for recognizing a pattern according to the present invention;

FIG. 30 is a semi-cartoon flow diagram of the object decomposition and recognition method of the present invention; and

FIG. 31 is a block diagram of an adaptive interface system according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiments of the present invention will now be described with reference to the Figures. Identical elements in the various figures are designated with the same reference numerals.

EXAMPLE 1 VCR Interface

A preferred embodiment of the interface of the present invention, described in the present example, provides automatic sequencing of steps, leading the user through the correct sequence of actions to set a program on the screen, so that no necessary steps are omitted, and no optional steps are accidentally or unintentionally omitted. These steps are shown diagrammatically in FIG. 15 of the present invention. In addition, such a system does not burden the user with the necessity of inputting superfluous information, nor overwhelm the user with the display of unnecessary data. See, Hoffberg, Linda I., “AN IMPROVED HUMAN FACTORED INTERFACE FOR PROGRAMMABLE DEVICES: A CASE STUDY OF THE VCR”, Master's Thesis, Tufts University; Hoffberg, Linda I., “Designing User Interface Guidelines For Time-Shift Programming of a Video Cassette Recorder (VCR)”, Proc. of the Human Factors Soc. 35th Ann. Mtg. pp. 501–504 (1991); and Hoffberg, Linda I., “Designing a Programmable Interface for a Video Cassette Recorder (VCR) to Meet a User's Needs”, Interface 91 pp. 346–351 (1991). See also, U.S. patent application Ser. No. 07/812,805, incorporated herein by reference in its entirety, including appendices and incorporated references.

Many design considerations were found to be important in the improved interface of the present invention:

The interface should preferably employ only-minimal amounts of abbreviations and the use of complete words is especially preferred, except where a standard abbreviation is available or where an “iconic” or symbolic figure or textual cue is appropriate. Thus, standard abbreviations and symbols are acceptable, and displayed character strings may be shortened or truncated in order to reduce the amount of information that is to be displayed, where necessary or desirable. An option may be provided to the user to allow full words, which may decrease the information which may be conveyed on each screen and increase the number of screens that must be displayed, or abbreviations and symbols, which may minimize the number of displayed screens of information, thus allowing the user to make the compromise. This aspect of the system may also be linked to the adaptive user level function of the present invention, wherein abstract symbols and abbreviations are presented to advanced users, while novices are presented with full words, based on an implicit indication of user level. These abstract symbols and abbreviations may be standard elements of the system, or user designated icons. Of course, the user could explicitly indicate his preference for the display type, thus deactivating the automatic adaptive user level function.

If multiple users use the device, then the device identifies the relevant users. This may be by explicit identification by keyboard, bar code, magnetic code, smart card (which may advantageously include a user profile for use with a number of devices), an RF-ID or IR-ID transponder, voice recognition, image recognition, or fingerprint identification. It is noted that smart cards or other intelligent or data-containing identifications systems may be used with different types of devices, for example video, audio, home appliances, HVAC and automobile systems.

Where a new user is identified to the system, an initial query may be made to determine an optimum initial user level. This allows further identification of the user and preference determination to occur more efficiently.

In applications in which a user must program an event on a certain date, at a certain time, a built-in calendar menu screen is preferably employed so that the user cannot set the device with a program step that relies on a non-existent date. Technology that will help eliminate the human problem of setting the wrong (yet existing) date may also be employed. Such technology might include accessing an on-line or other type of database containing media programming information, and prompting the user regarding the selected choice. In situations where it is applicable, the interface should indicate to the user the number of characters the interface is expecting, such as when entering the year.

The interface system provides an easily accessible CHANGE, CANCEL or UNDO (single or multiple level) feature, which facilitates backtracking or reprogramming the immediately previously entered information rather than forcing the user to repeat all or a substantial portion of the programming steps. A method of the type described is shown in FIG. 16 of the present invention. User input is also facilitated by the provision of frequently used settings as explicit choices, such as, referring to the VCR example, “Record today,” “Record tomorrow,” “Noon,” and “Midnight,” so that the user does not have to specify a date in these cases. This will eliminate extra keypresses, and reduce the programming time. In addition, this could eliminate user errors. Frequently used choices for program selections are also provided to the user to reduce the number of programming steps necessary and provide the user with all the frequently used selections. The especially preferred choices are “Once On.”, “Once a Week on .”, “Monday–Friday at.”, “Everyday at.”. These redundant, complex instructions reduce the number of keystrokes required for data entry, and reduce the amount of programming time required.

The presently described interface system also provides, in the event that a color screen is available, conservatively used color coding, which allows the user to effectively and quickly acknowledge the function of each aspect of the screen. When programming, the preferred colors are royal blue for “help,” red for mistakes, light blue for information previously entered, and yellow for current information being entered. Of course, other colors could be used, according to the user's or designer's preference, cultural differences, and display parameters.

When viewing, it is preferable that screen colors change to indicate status changes, such as viewed/unviewed, or to categorize the shows.

The interface includes a confirmation screen which displays to the user all of the categories and selections previously explicitly entered or otherwise inferred, and should be easily understandable. This is shown in FIG. 15 of the present invention. All of the necessary information is displayed on this screen, in addition to the change and cancel options, if possible.

The entering of information on each screen is preferably consistent throughout the various interface options and levels. All of the screens preferably have similar layouts. “Buttons” or screen locations which are keyed to a particular function, which appear on multiple screens, should appear in approximately the same location on all screens. However, in certain cases, relatively more important information on a given screen may be displayed more prominently, and possibly in a different screen location, in order to reduce the search time. Further, when other factors dictate, each screen may be independently optimized for the prescribed function. For example, a representation of an analog clock dial may be used to set time information. However, even if the format does change, a standard scheme should be maintained, such as the use of a particular color to indicate that a particular program aspect has been changed.

The interface should display data consistent with standards and conventions familiar to users. For, e.g., when entering dates, users are most familiar with calendars. However, this type of presentation of choices does not eliminate the human problem of entering incorrect information, e.g., setting a wrong, but existing, date. The problem of ensuring the accuracy of user input may be addressed by an intelligent interface which stores data concerning programming, user preferences, and by means of some logical method, such as Boolean logic, fuzzy logic, neural network theory, or any other system which may be used to generate a prediction, to determine if an entry is likely in error, by comparing the prediction with the entry. Of course, these predictive systems would also provide an initial default entry, so that an a priori most probably action or actions may be initially presented to the user.

In addition to following conventions of information presentation to the user, the interface of the present invention may also provide emulations of other user interfaces of which a particular user may be familiar, even if these are not optimized according to the presently preferred embodiments of the present invention, or not otherwise well known. These emulations need not even be of the same type of device, so that a broad based standard for entry of information into a programmable controls, regardless of their type, may be implemented. By allowing emulation, the interface could provide compatibility with a standard or proprietary interface, with enhanced functionality provided by the features of the present interface.

These enhanced functional intelligent aspects of the controller may be implemented by means of software programming of a simple microcomputer, or by use of more specialized processors, such as a Fuzzy Set Processor (FSP) or Neural Network Processor to provide real-time responsiveness, eliminating delays associated with the implementation of complex calculations on general purpose computing devices.

In the various embodiments according to the present invention, various control strategies are employed. Depending on the application, fuzzy set processors (FSP's) may be preferred because they have the advantage of being easier to program through the use of presumptions or rules for making the fuzzy inferences, which may be derived by trial and error or the knowledge of experts, while Neural Networks are less easily explicitly programmed and their network weighing values are not easily understood in the abstract, but these systems may be applied to learn appropriate responses from test data. Thus, neural networks tend to require extensive “training”, while Fuzzy Set Processors may be explicitly programmed without the need of duplicating or simulating actual operating conditions, but may require “fine tuning”.

The most frequently used choices preferably should be displayed as the default setting. The screen cursor preferably appears at the “accept” screen button, when the screen is displayed. This default can either be set in advance, or acquired by the system. In the case of acquired defaults, these may be explicitly set by the user or adaptively acquired by the system through use. The interface of the present invention may be taught, in a “teach” mode, the preferences of the user, or may also acquire this information by analyzing the actual choices made by the user during operation of the interface and associated controller. This type of operation is shown schematically in FIG. 15 of the present invention. The options of “Midnight” (12:00 AM) and “Noon” (12:00 PM) should preferably be present, as some people often become confused when distinguishing between them. Icons, such as those indicative of the “sun” and the “moon”, may also be used to facilitate data entry for AM and PM. The interface should preferably utilize an internal clock and calendar so that the user cannot set the time or program to record on a nonexistent date. Such a system could also compensate for daylight-savings time seasonal adjustments.

The cursor is preferably distinctive and readily distinguished from other parts of the screen. This may be by color, attribute (i.e. blinking), size, font change of underlying text, or by other means.

The user can preferably exit the programming sequence at any time by selecting a “Main Menu” button which may exist on the lower left-hand corner of every screen. The user is preferably provided with an adequate amount of feedback, and error messages should be directive in nature. Some form of an acknowledgement is preferably displayed after each entry. The user should preferably not be able to go to the next programming step until the current step has been completed. A message to convey why the user can not continue should appear when an attempt to prematurely continue is recognized.

The “help” function is available for when the user does not know what to do. The “help” screen(s) preferably explains the functions of each of the available buttons or functions, but may also be limited to those that are ambiguous. The “help” screen may also be used to indicate a current status of the interface and the controller. Further, the “help” function may also provide access to various other functions, such as advanced options and configurations, and thus need not be limited to merely providing information on the display. The help system may incorporate a hypertext-type system, wherein text or information relating to concepts that are conceptually linked may be easily accessed by indicating to the interface system that the related information is desired. To eliminate the possibility of the user trying to make selections on merely informative help screens, the cursor, in these cases, should be locked to a choice which returns the user to where they left off in the programming sequence, and this choice should be highlighted.

The “help” function may also comprise “balloon help” similar to the system adopted by Apple Computer, Inc. in Macintosh Operating System, e.g., 7.0, 7.1, 7.5, etc.

The interface preferably initiates the programming sequence where the user wants to be, so that the interface has so-called “smart screens”. For example, when a VCR is first powered up or after an extended power failure, and the time and date are not stored in the machine, the “set date” and “set time” screens should appear. The sequence of screens may also vary depending on the system predicted requirements of the user and various aspects of the improved interface of the present invention. This is shown schematically in FIG. 17 of the present invention.

The preferable input device for the interface of the present invention provides as few buttons as possible to achieve the required functionality, thus reducing potential user intimidation, focusing the user's attention on the interactive display screen, where the available choices are minimized to that number necessary to efficiently allow the user to program the discrete task presented. Such a minimization of discrete inputs facilitates a voice recognition input, which may be used as an alternative to mechanical input devices. The preferred embodiment includes a direct-manipulation type interface, in which a physical act of the user causes a proportionate change in the associated interface characteristic, such as cursor position. A computer mouse, e.g. a two dimensional input device, with 1 to 3 buttons is the preferred input device, for use with a general purpose computer as a controller, while a trackball on a remote control device is especially preferred for limited purpose controllers because they do not require a flat surface for operation. Other stationary or movement sensitive input devices may, of course be used, such as joysticks, gyroscopes, sonic echo-location, magnetic or electrostatic location devices, RF phase location devices, Hallpots (joystick-like device with magnets that move with respect to Hall effect transducers), etc. The present interface minimizes the number of necessary keys present on an input device, white maintaining the functionality of the interface. It is noted that a strict minimization without consideration of functionality, might lead to inefficiency. For example, in a VCR device, if the user wants to record a program which airs Monday through Friday, he would have to set five separate programs, rather than one program if a “weeknights” choice is made available.

The interface preferably should be easy to learn and should not require that a user have prior knowledge of the interface in order to use it. An attempt has been made to minimize the learning curve, i.e., to minimize the time it takes to learn how to use the device.

Menu options are preferably displayed in logical order or in their expected frequencies. Research has shown that a menu-driven interface is best for applications involving new users and does not substantially hinder experienced users. Menu selection is preferably used for tasks which involve limited choices. They are most helpful for users with little or no training. Each menu should preferably allow only one selection at a time. Most of the information is preferably entered using a numeric keypad (entry method), rather than using up and down arrow keys (selection method). In addition, no leading zeros are required for entry. If there is more than one keystroke required, the user must then select an “OK” button to continue in the programming sequence. However, if the selection method is used, all of the choices are displayed on the screen at once. The number of steps required to complete the task through a sequence of menus should be minimized. The choice of words used to convey information should not be device specific, i.e., computer terms, but rather normal, everyday terms which are easy to understand. In addition, very few abbreviations should be used. All necessary information which the user needs should preferably be displayed at once. A user preferably should not have to rely on his memory or his previous experience, in order to find the correct choice, at least at the lower user levels. If all selections cannot be displayed at once, a hierarchical sequence is preferably used. A main menu should preferably provide a top level to which the user can always return and start over.

Searching and learning times should be kept to a minimum in order to obtain a subjectively better interface. The system's logic should reflect the users' expectations, offer visual clues and feedback, and stay within human memory limits. For example, the VCR should turn on not only with the “Power” button, but also when inserting a tape into the device. In addition, the sequence of steps for setting the machine to record, if the user does not indicate implicitly or explicitly that he knows how to use the device, should assume that the user is a novice, and fully prompt the user for elemental items of information. Nothing should be taken for granted. By developing an improved interface, an attempt is made to: reduce the searching time; reduce the learning time; simplify the entering of data; and, reduce the intimidation experienced by certain persons when using electronic devices.

Tests by an inventor hereof show that people do not program their VCRs often, and they often forget the sequence of steps between recording sessions. Thus, the present invention preferably incorporates an adaptive user level interface, wherein a novice user is presented with a simpler interface with fewer advanced features initially available, so that there is reduced searching for the basic functions. A more advanced user is presented with more advanced choices and functions available initially, as compared to a novice user.

Thus, as shown in FIG. 17, the user identifies himself to the controller in block 1701. The controller 1806 of FIG. 18 thereafter uses a stored profile of the identified user in controlling the interaction with the user, as shown in block 1702 of FIG. 17, from information stored in the database 1807 of FIG. 18 of the present invention. It has been found that in the case of novice users, a greater number of simple instructions may be more quickly and easily input rather than a potentially fewer number of a larger set of more complex instructions. It has further been found that, even if presented with a set of instructions which will allow a program to be entered with a fewer number of inputs, a novice user may choose to input the program using the simple instructions exclusively, thus employing an increased number of instructions and being delayed by an increased search time for those instructions that are used, from the larger set.

Other characteristics of this interface include color coding to help prompt the user as to which data must be entered. Red text signifies instructions or errors, yellow text represents data which must be entered or has not been changed, and blue text shows newly entered program data or status information. Blue buttons represent buttons which should normally be pressed during the programming sequence. Red buttons signify an erratic pattern in the data entry, such as the “cancel” and “return to main menu” buttons. Of course, these colors can be replaced by other display attributes, such as intensity, underline, reverse video, blinking and pixel dithering pattern, in addition to the use of various fonts. Such a situation would include a monochrome monitor or display.

The date may be entered in the form of a calendar rather than as numbers (i.e., “Sep. 6, 1991”). This calendar method is advantageous because users may wish to input date data in one of three ways: day of the week, day relative to the present, and day of the month. The present method allows the current date to be highlighted, so that the calendar may be used to easily enter the absolute day, absolute date, and relative day. Further, the choices “today” and “tomorrow”, the most frequently used relative recording times, are included in addition to a month-by-month calendar. This information is provided to avoid an unnecessary waste of time and user frustration. Thus, another aspect of the present invention is to provide a partially redundant interactive display input system which allows, according to the highest probability, the choices to be prominently displayed and easily available, in addition to allowing random access to all choices.

The present device allows common user mistakes to be recognized and possibly addressed, such as the confusion between 12:00 PM and 12:00 AM with midnight and noon, respectively. Therefore, the options of “noon” and “midnight” are provided in addition to a direct numeric clock input. When entering time information, leading zeros need not be entered, and such information may be entered in either fashion.

The criteria for system acceptance of input depends on how many keystrokes are required on the screen. If only one keystroke is required to complete input of the information, upon depressing the key, the programming sequence will continue. If more than one keypress is required, the user must depress the “OK” button to continue programming. This context sensitive information entry serves to avoid unnecessary input.

An on-line “help” system and on-line feedback is preferably provided to the user throughout various aspects of the interface. Other features include minimizing the number of keypresses required to program the device. These features, together with other aspects of the present invention allow the user to achieve a greater efficiency with the input device than with prior art devices.

The interface of the present invention applied to a VCR control preferably comprises a virtual keypad entry device (i.e. a representation of an array of choices), a directional input control for a cursor on a display screen, and selection buttons. The input device has an input corresponding to a direction of movement relative to the cursor position. Thus, since the present input device seeks to minimize the physical control elements of the human interface device, the display elements for a preferred embodiment of the present interface include:

-   -   1. number keys 0–9.     -   2. enter key.     -   3. cancel key.     -   4. status indicator.     -   5. return to menu option button.     -   6. program type indicator: program once, program once a week,         program Monday-Friday, program everyday.     -   7. Day indicators: 7 week days, today, tomorrow.     -   8. Noon and midnight choices.     -   9. Help button.     -   10. Main menu options: Review, Enter new recording time, Set         time, Set date.     -   11. Timer button.     -   12. Power button.     -   13. AM/PM choices.     -   14. 31 day calendar.     -   15. 12 month Choices.     -   16. 3 tape speed choices.

User dissatisfaction is generally proportionate to the length of “search time,” the time necessary in order to locate and execute the next desired function or instruction. Search time may be minimized by the inclusion of up to a maximum of 4–8 choices per screen and by use of consistent wording and placement of items on the display.

The present invention proceeds from the understanding that there are a number of aspects of a programmable interface that are desirable:

First, users should be able to operate the system successfully, without wide disparities in time. It should take, e.g., a normal person interacting with a VCR interface, less than seven minutes to set the time and two programs. Searching time spent in setting the clock, programming, getting into the correct mode, and checking whether or not the VCR is set correctly should be kept to a minimum through the appropriate choices of menu layout and the presentation of available choices.

Second, programming should be a stand-alone process, and not require an instruction manual. A help system should be incorporated in the interface. Word choices should be understandable, with a reduction in the use of confusing word terminology. Error messages should be understandable. The system should provide the ability to cancel, change or exit from any step.

Third, the system should provide on-screen understandable information, with adequate visual feedback. The displays should be consistent. Color coding should be employed, where applicable, using, e.g. blue—new input; red—error condition; yellow—static, unchanged value. Layouts should be logical, and follow a predictable pattern. There should be a maximum of 4–8 choices per screen to minimize searching time. Keys should be labeled with text rather than with ambiguous graphics. However, a combination of both may be preferable in some cases.

Fourth, steps required to complete tasks should be simple, require a short amount of time and not create user frustration. The system should guide the user along a decision path, providing automatic sequencing of steps. The most frequently used choices should be provided as defaults, and smart screens may be employed. The learning curve should be minimized through the use of easily understandable choices. As a user becomes more sophisticated, the interface may present more advanced choices.

Fifth, there should be a reminder to set the timer and to insert the tape once the programming information is entered. This reminder may also be automated, to eliminate the commonly forgotten step of setting the timer, so that the VCR automatically sets the timer as soon as the necessary information is entered and a tape is inserted. Once the program is set in memory, a message should appear if a tape is not inserted. If the VCR is part of a “jukebox” (automatic changer), the tape may be automatically loaded. The VCR should preferably turn on when a tape is inserted. In addition, users should also be able to control the VCR with a Power button.

Sixth, the VCR should be programmable from both the remote device and the control panel.

Seventh, each operation should require only one keypress, if possible, or otherwise reduce the number of keypresses required. There should be a 12 hour clock, not a 24 hour clock. There should be an on-screen keypad with entry keys, not “up” and “down” selector keys, allowing for the choice of specific day or time entry. There should be a “start” and a “stop” recording time, rather than “start” time and “length of program” or duration exclusively. The number of buttons on the remote control should be minimized so that as few buttons as are required are provided. The input device should provide for the direct manipulation of screen elements. A menu driven interface should be provided.

The interface of the present invention provides an automatic sequencing of steps which does not normally let the user think the previous step is complete. This is shown schematically in FIG. 16. In this manner, important steps will not be inadvertently omitted. Upon entering the programming sequence, if the current date or time is not set, the interface will prompt the user to enter this information. Thereafter, the interface will normally default to the main menu, the most frequently used first screen. Thus, the interface of the present invention is adaptive, in that its actions depend on the current state of the device, including prior programming or use of the device by the user. It can be appreciated that this adaptive behavior can be extended to include extended “intelligence”. For example, if the device is similarly programmed on a number of occasions, then the default setup may be adapted to a new “normal” program mode. Further, the apparatus could provide multiple levels of user interface, e.g. beginner, intermediate, and advanced, which may differ for various functions, based on the behavior of the user. This user interface level determining feature extraction system is shown diagrammatically in FIG. 18. In contrast, prior art interfaces that have different user interface levels, allow the user to explicitly choose the interface level, which will then be used throughout the system until reset.

The present system allows discrete tasks to be conducted more quickly, more efficiently, with reduced search time and with fewer errors than prior art systems.

EXAMPLE 2 Serial Recording Medium Index

In a preferred embodiment of the present invention, in a VCR, in order to track the content of the tape, a directory or a catalog is recorded, preferably digitally, containing the programming information, as well as additional information about the recorded programs, in a header, i.e., at the beginning of the tape, or at other locations on the tape. The device may also catalog the tape contents separately, and based on an identification of the tape, use a separately stored catalog. A preferred format for storing information is shown in FIG. 19.

Thus, if there are a number of selections on the tape, the entire contents of the tape could be accessible quickly, without the need for searching the entire tape. In a sequential access medium, the tape transport apparatus must still shuttle to the location of the desired material, but it may do so at increased speeds, because there is no need to read the tape once the location is determined; after the tape transport nears the desired spot, the tape may be slowed or precisely controlled to reach the exact location.

The tape read and drive system is shown schematically in FIG. 20. The algorithm used in the final stage of approach to the desired portion of the tape or other recording medium may incorporate a control employing Fuzzy logic, Neural Networks, mathematical formulae modeling the system (differential equations) in a Model-based system, a Proportional-Differential-Integral (PID) system, or a controller employing an algorithm of higher order, or other known control methods.

If a selection is to be recorded over, the start and stop locations would be automatically determined from the locations already indicated on the tape. Further, this information could be stored in memory device (which reads a catalog or index of the tape when a new tape is loaded) or non-volatile memory device (which stores information relating to known tapes within the device) or both types of memory in the VCR, so that an index function may be implemented in the VCR itself, without the need to read an entire tape. Optionally, a printer, such as a thermal label printer (available from, e.g. Seiko Instruments, Inc.), attached to the device, could be available to produce labels for the tapes, showing the index, so that the contents of a tape may be easily indicated. A label on the tape may also include a bar code or two-dimensional coding system to store content or characterization information. The stored identification and index information is thus stored in a human or machine readable form.

These contents, or a list of contents, need not necessarily be manually entered by the user or created by the apparatus, rather, these may be derived from published data or a database, data transmitted to the control, and/or data determined or synthesized by the control itself. For example, broadcast schedules are available in electronic or machine readable form, and this information may be used by the apparatus.

EXAMPLE 3 Serial Data Medium Index

Another aspect of the present invention relates to the cataloging and indexing of the contents of a storage medium. While random access media normally incorporate a directory of entries on a disk, and devices such as optical juke boxes normally are used in conjunction with software that indexes the contents of the available disks, serial access mass storage devices, such as magnetic tape, do not usually employ an index; therefore, the entire tape must be searched in order to locate a specific selection.

In the present invention, an area of the tape, preferable at the beginning of the tape or at multiple locations therein, is encoded to hold information relating to the contents of the tape. This encoding is shown in FIG. 19, which shows a data format for the information. This format has an identifying header 1901, a unique tape identifier 1902, an entry identifier 1903, a start time 1904, an end time 1905 and/or a duration 1906, a date code 1907, a channel code 1908, descriptive information 1909 of the described entry, which may include recording parameters and actual recorded locations on the tape, as well as a title or episode identifying information, which may be a fixed or variable length entry, optionally representative scenes 1910, which may be analog, digital, compressed form, or in a form related to the abstract characterizations of the scenes formed in the operation of the device. Finally, there are error correcting codes 1911 for the catalog entry, which may also include advanced block encoding schemes to reduce the affect of non-Gaussian correlated errors which may occur on video tape, transmission media and the like. This information is preferably a modulated digital signal, recorded on, in the case of Hi-Fi VHS, one or more of the preexisting tracks on the tape, including the video, overscan area, Audio, Hi-Fi stereo audio, SAP or control tracks. It should be noted that an additional track could be added, in similar fashion to the overlay of Hi-Fi audio on the video tracks of Hi-Fi VHS. It is also noted that similar techniques could be used with Beta format, 8 mm, or other recording systems, to provide the necessary indexing functions.

Digital data may also be superimposed as pseudonoise in the image information, or as other information intermixed or merged with the video information.

The recording method is preferable a block encoding method with error correction within each block, block redundancy, and interleaving. Methods are known for reducing the error rate for digital signals recorded on unverified media, such as videotape, which are subject to burst errors and long term non-random errors. Such techniques reduce the effective error rate to acceptable levels. These are known to those skilled in the art and need not be discussed herein in detail. A standard reference related to this topic is Digital Communications by John G. Proakis, McGraw-Hill (1983). The digital data recording scheme is best determined according to the characteristics of the recording apparatus. Therefore, if an, e.g. Sony Corporation helical scan recording/reproducing apparatus was employed, one of ordinary skill in the art would initially reference methods of the Sony Corporation initially for an optimal error correcting recording scheme, which are available in the patent literature, in the U.S., Japan, and internationally, and the skilled artisan would also review the known methods used by other manufacturers of digital data recording equipment. Therefore, these methods need not be explained herein in detail.

The catalog of entries is also preferably stored in non-volatile memory, such as hard disk, associated with the VCR controller. This allows the random selection of a tape from a library, without need for manually scanning the contents of each tape. This also facilitates the random storage of recordings on tape, without the requirement of storing related entries in physical proximity with one another so that they may be easily located. This, in turn, allows more efficient use of tape, because of reduced empty space at the end of a tape. The apparatus is shown schematically in FIG. 20, in which a tape drive motor 2001, controlled by a transport control 2002, which in turn is controlled by the control 2003, moves a tape 2005 past a reading head 2004. The output of the reading head 2004 is processed by the amplifier/demodulator 2006, which produces a split output signal. One part of the output signal comprises the analog signal path 2007, which is described elsewhere. A digital reading circuit 2008 transmits the digital information to a digital information detecting circuit 2009, which in turn decodes the information and provides it to the control 2003.

In order to retrieve an entry, the user interacts with the same interface that is used for programming the recorder functions; however, the user selects different menu selections, which guide him to the available selections. This function, instead of focusing mainly on the particular user's history in order to predict a selection, would analyze the entire library, regardless of which user instituted the recording. Further, there would likely be a bias against performing identically the most recently executed function, and rather the predicted function would be an analogous function, based on a programmed or inferred user preference. This is because it is unlikely that a user will perform an identical action repeatedly, but a pattern may still be derived.

It is noted that the present library functions differ from the prior art VHS tape index function, because the present index is intelligent, and does not require the user to mark an index location and explicitly program the VCR to shuttle to that location. Rather, the index is content based. Another advantage of the present library function is that it can automatically switch media and recording format, providing an adaptive and/or multimode recording system. Such a system might be used, for example, if a user wishes to record, e.g., “The Tonight Show With Johnny Carson” in highly compressed form, e.g. MPEG-2 at 200:1 compression, except during the performance of a musical guest, at which time the recording should have a much lower loss, e.g., MPEG-2 at 20:1, or in analog format uncompressed. A normal VCR could hardly be used to implement such a function even manually, because the tape speed (the analogy of quality level) cannot generally be changed in mid recording. The present system could recognize the desired special segment, record it as desired, and indicate the specific parameters on the information directory. The recorded information may then be retrieved sequentially, as in a normal VCR, or the desired selection may be preferentially retrieved. If the interface of the present invention is set to automatically record such special requests, the catalog section would then be available for the user to indicate which selections were recorded based upon the implicit request of the user. Because the interface has the ability to characterize the input and record these characterizations in the index, the user may make an explicit request different from the recording criteria, after a selection has been recorded. The controller would then search the index for matching entries, which could then be retrieved based on the index, and without a manual search of the entire tape. Other advantages of the present system are obvious to those of ordinary skill in the art.

A library system is available from Open Eyes Video, called “Scene Locator”, which implements a non-intelligent system for indexing the contents of a videotape. See NewMedia, November/December 1991, p. 69.

It is noted that, if the standard audio tracks are used to record the indexing information, then standard audio frequency modems and recording/receiving methods are available, adapted to record or receive data in half-duplex mode. These standard modems range in speed from 300 baud to about 64 kilobits per second, e.g. v.29, v.17, v.32, v.32bis, v.34, v.90, v.91, etc. While these systems are designed for dial-up telecommunications, and are therefore are designed for the limited data rates available from POTS. These are limited to a slower speed than necessary and incorporate features unnecessary for closed systems, they require a minimum of design effort and the same circuitry may be multiplexed and also be used for telecommunication with an on-line database, such as a database of broadcast listings, discussed above. It should be noted that a full-duplex modem should be operated in half duplex mode when reading or recording on a media, thus avoiding the generation of unnecessary handshaking signals. Alternatively, a full duplex receiver may be provided with the resulting audio recorded. A specially programmed receiver may extract the data from the recording. DTMF codes may also be employed to stored information.

The Videotext standard may also be used to record the catalog or indexing information on the tape. This method, however, if used while desired material is on the screen, makes it difficult (but not impossible) to change the information after it has been recorded, without re-recording entire frames, because the videotext uses the video channel, during non-visible scan periods thereof. The video recording system according to the present invention preferably faithfully records all transmitted information, including SAP, VAR, close caption and videotext information, which may be used to implement the various functions.

The use of on-line database listings may be used by the present interface to provide information to be downloaded and incorporated in the index entry of the library function, and may also be used as part of the intelligent determination of the content of a broadcast. This information may further be used for explicitly programming the interface by the user, in that the user may be explicitly presented with the available choices available from the database.

EXAMPLE 4 Controlled Encryption and Accounting System

The present invention also allows for scrambling, encryption and locking of source material, and the receiving device selectively implements an inverse process or a partial inverse process for descrambling, decryption or unlocking of the material, much as the Videocipher series systems from General Instruments, and the fractal enciphering methods of Entertainment Made Convenient² Inc. (EMC², and related companies, e.g., EMC³, and Iterated Systems, Inc. The present invention, however, is not limited to broadcasts, and instead could implement a system for both broadcasts and prerecorded materials. In the case of copying from one tape to another, such a system could not only provide the herein mentioned library functions of the present invention according to Example 2, it could also be used to aid in copy protection, serial copy management, and a pay-per-view royalty collection system.

Such a system could be implemented by way of a telecommunication function incorporated in the device, shown as block 1808 of FIG. 18, or an electronic tag which records user activity relating to a tape or the like. Such tags might take the form of a smart card, PCMCIA device, or other type of storage device. A royalty fee, etc., could automatically be registered to the machine either by telecommunication or registry with the electronic tag, allowing new viewer options to be provided as compared with present VCR's.

Numerous digital data encryption and decryption systems are known. These include DES, “Clipper”, elliptic key algorithms, public key/private key (RSA, etc.), PGP, and others. Digital encryption allows a sender to scramble a message so that, with an arbitrary degree of difficulty, the message cannot be determined without use of a decryption key.

An encrypted tape or other source material may be decrypted with a decryption key available by telecommunication with a communication center, remote from the user, in a decryption unit, shown schematically as the decrypt unit 1806 a of FIG. 18. Such an encryption/decryption scheme requires special playback equipment, or at least equipment with decryption functionality, and thus any usage or decrypted data may be registered as a result of the requirement to receive a decryption key. The decryption unit may be part of an addressable remote unit for control of the unit remotely.

During acquisition of the electronic decryption key, a VCR device of an embodiment of the present invention would indicate its identity or electronic address, and an account is charged a fee for such use. The negotiation for the electronic key is also preferably encrypted. In addition, the decryption key may be specific for a particular decoder. Such a system could also be used for controlled access software, for example for a computer, wherein a remote account is charged for use of the software. Information communication may be through the Internet or through an on-line service such as America Online or Compuserve.

Such a system differs from the normal hardware “key” or “dongle” (device which attaches to standard hardware port for authentication and usage limitation) because it requires on-line or electronic access for an encryption key, which may offer different levels of use. It also differs from a call-in registration, because of the automatic nature of the telecommunication. This presently described system differs from normal pay-per-view techniques because it allows, in certain instances, the user to schedule the viewing. Finally, with an encryption function implemented in the VCR, the device allows a user to create and distribute custom “software” or program material. In addition, the present controller could then act as the “telecommunication center” and authorize decryption of the material.

If the source signal is in digital form, a serial copy management scheme system is preferably implemented.

The present invention is advantageous in this application because it provides an advanced user interface for creating a program (i.e. a sequence of instructions), and it assists the user in selecting from the available programs, without having presented the user with a detailed description of the programs, i.e., the user may select the choice based on characteristics rather than literal description.

In the case of encrypted program source material, it is particularly advantageous if the characterization of the program occurs without charging the account of the user for such characterization, and only charging the account if the program is viewed by the user. The user may make a viewing decision based on the recommendation of the interface system, or may review the decision based on the title or description of the program, or after a limited duration of viewing. Security of the system could then be ensured by a two level encryption system, wherein the initial decryption allows for significant processing, but not comfortable viewing, while the second level of decryption allows viewing, and is linked to the accounting system. Alternatively, the decryption may be performed so that certain information, less than the entirety, is available in a first decryption mode, while other information comprising the broadcast information is available in a second decryption mode.

The transmission encryption system may be of any type, but for sensitive material. i.e. where mere distortion of the material (e.g., loss of synchronization information and phase distortion) would be insufficient, an analog multiple subband transform, with spread spectrum band hopping and digital encryption of various control signals, would provide a system which would be particularly difficult for the user to view without authorization, and could be effectively implemented with conventionally available technology. The fractal compression and encryption of the EMC² and Iterated Systems, Inc. system is also possible, in instances where the broadcast may be precompressed prior to broadcast and the transmission system supports digital data. Of course, if a digital storage format is employed, a strict digital encryption system of known type may be used, such as those available from RSA. The implementation of these encryption systems is known to those skilled in the art. These may include the National Bureau of Standards (NBS), Verifiable Secret Sharing (VSS) and National Security Agency (NSA) encryption standards, as well as various proprietary standards.

EXAMPLE 5 User Interface

In one embodiment of the present invention, the apparatus comprises a program entry device for a VCR or other type of media recording system. The human interface element has an infrared device to allow wireless communication between the human interface device and the VCR apparatus proper. The human interface device also includes a direct-manipulation type input device, such as a trackball or joystick. Of course it is understood that various known or to-be developed alternatives can be employed, as described above.

It is noted that many present devices, intended for use in computers having graphic interfaces, would advantageously make use of an input device which is accessible, without the necessity of moving the user's hands from the keyboard. Thus, for example, Electronic Engineering Times (EET), Oct. 28, 1991, p. 62, discloses a miniature joystick incorporated into the functional area of the keyboard. This technique is directed at a different aspect of user interaction with a programmable device than certain preferred embodiments of the present invention, in that the input device does not have a minimal number of keys. While the device disclosed in EET is intended for use in a full function keyboard, the preferred embodiment of the present invention is directed towards the minimization of the number of keys and avoidance of superfluous keys by provision of a pointing device. Of course, the present invention could be used with a full function input device, where appropriate, and the joystick of EET (Oct. 28, 1991, p. 62) would be suitable in this case.

The interface of the present invention studies the behavior and moods of the user, in context, during interactions to determine the expected user level of that user as well as the preferences of the user. These user characteristics may change over time and circumstances. This means that the system studies the interaction of the user to determine the skill of the user or his or her familiarity with the operation and functionality of the system. By determining the skill of the user, the system may provide a best compromise. The purpose of this feature is to provide a tailored interface adapted to the characteristics of the user, thus adaptively providing access to various features in a hierarchical manner such that a most likely feature to be used is more easily accessible than an unlikely feature, but that features can generally be accessed from all or most user levels. The user level analysis also allows the system to teach the user of the various functions available, particularly when it becomes apparent that the user is being inefficient in the use of the system to perform a given task. Therefore, the menu structure may also be adaptive to the particular task being performed by the user. When combined with the user level analysis feature, the user efficiency feature will provide a preferable interface, with reduced learning time and increased usability for a variety of users.

Thus, an important concept is that the system has at least one object having a plurality of functions, certain of which are unnecessary or are rarely used for various applications or in various contexts, while these are used with greater frequency in other contexts. Further, based upon predetermined protocols and learned patterns, it is possible to predict which functions will be used and which will not be used.

Therefore, the system, upon recognizing a context, will reconfigure the availability or ease of availability of functions and allow various subsets to be used through “shortcuts”. Thus, to some extent, the interface structure may vary from time to time based upon the use of the system. The prior art apparently teaches away from this concept, because it is believed to prevent standardization, limits the “recordability” of macros and/or instruction sheets for casual users and limits the availability of technical support. Each of these can be addressed, to some extent by the availability of a default mode (so that users can access all information), and because the interface is self-simplifying in case of difficulty. However, forcing all users to always work in a default mode limits the improvements in productivity that may be gained by a data-sensitive processing system, and hence this standardization for its own sake is rejected by the present invention.

The improvements to be gained by using an intelligent data analysis interface for facilitating user control and operation of the system are more than merely reducing the average number of keystrokes or time to access a given function. Initial presentation of all available information to a new user might be too large an information load, leading to inefficiency, increased search time and errors. Rather, the improvements arise from providing a means for access of and availability to functions not necessarily known to the user, and to therefore improve the perceived quality of the product.

The system to determine the sophistication of the user includes a number of storage registers, for storing an analysis of each act for each user. A given act is represented in a plurality of the registers, and a weighting system to ensure that even though an act is represented in a number of registers, it is not given undue emphasis in the analysis. Thus, each act of the user may be characterized in a number of ways, and each characteristic stored in an appropriate register, along with a weighting representing an importance of the particular characteristic, in relation to other identified characteristics and in relation to the importance of the act as a whole. The act is considered in context, and therefore, the stored information relates to the act, the sequence of acts prior to the act, acts of the user occur after the act, the results of the sequence of acts which include the act, and characteristics of the user which are not “acts”, but rather include timing, mouse path efficiency, and an interaction with other users.

An apparatus for performing a path information or efficiency determining function is shown schematically in FIG. 18, and in more detain in FIG. 21. Thus, for example, if a characteristic of the user is an unsteady hand while using the cursor control device, e.g. mouse, producing a high frequency or oscillating component, the existence of this characteristic is detected and quantified by the high frequency signal component detector 2112, and, depending on the amplitude, frequency and duration (e.g. path length), may also be detected by the path optimization detector 2105. Once this characteristic is detected and quantified, an adaptive filter may be applied by the main control 1806 to selectively remove the detected component from the signal, in order to improve the reliability of the detection of other characteristics and to determine the intended act of the user.

It should be noted that the various characteristic filters preferably act in “parallel” at each stage of the characteristic recognition, meaning that one characteristic is defined simultaneously with the detection of other characteristics, which assists in resolving ambiguities, allows for parallel processing by a plurality of processing elements which improves real-time recognition speed, and allows a probability-based analysis to proceed efficiently. Such a “parallel” computation system is included in a neural net computer, and a hardware-implementation of a neural net/fuzzy logic hybrid computer is a preferred embodiment, which allows fuzzy rules to be programmed to provide explicit control over the functioning of the system. It is preferred that a human programmer determine the basic rules of operation of the system, prior to allowing a back-propagation of errors learning algorithm to improve and adapt the operation of the system.

The adaptive system implemented according to the present invention, by detecting a user level, allows a novice user to productively interact with the system while not unnecessarily limiting the use of the adaptive interface by an advanced user, who, for example, wishes to move the cursor quickly without the limiting effects of a filter which slows cursor response.

Another example of the use of an adaptive user interface level is a user who repeatedly requests “help” or user instructions, through the explicit help request detector 2115, which causes an output from the current help level output 2102; such a user may benefit from an automatic context-sensitive help system, however such a system may interfere with an advanced user, and is unnecessary in that case and should be avoided. This adaptive user interface level concept is not limited to a particular embodiment of the present invention, such as a VCR, and in fact, may be broadly used wherever a system includes an interface which is intended for use by both experienced and inexperienced users. This differs from normal help systems which must be specifically requested, or “balloon help” (Apple Computer, Macintosh System 7.0, 7.1, 7.5) which is either engaged or disengaged, but not adaptive to the particular situation based on an implicit request or predicted need. In the case of a single user or group of users, the interface could maintain a history of feature usage for each user, as in the past user history block 2107, and provide a lower user interface level for those features which are rarely used, and therefore less familiar to the user, through the current user level output 2101.

It should be noted that the present system preferably detects an identity of a user, and therefore differentiates between different users by an explicit or implicit identification system. Therefore, the system may accumulate information regarding users without confusion or intermingling.

EXAMPLE 6 VCR Programming Preference Prediction

The device according to the present invention is preferably intelligent. In the case of a VCR, the user could also input characteristics of the program material that are desired, and characteristics of that program material which is not desired. The device would then, over time, monitor various broadcast choices, and determine which most closely match the criteria, and thus be identified. For example, if the user prefers “talk-shows”, and indicates a dislike for “situation comedies” (“sitcoms”), then the device could scan the various available choices for characteristics indicative of one or the other type of programming, and perform a correlation to determine the most appropriate choice(s). A sitcom, for example, usually has a “laugh track” during a pause in normal dialogue. The background of a sitcom is often a confined space (a “set”), from different perspectives, which has a large number of “props” which may be common or unique. This set and the props, however, may be enduring over the life of a show.

A talk-show, on the other hand, more often relies on actual audience reaction (possibly in response to an “applause” sign), and not prerecorded or synthesized sounds. The set is simple, and the broadcast often shows a head and neck, or full body shot with a bland background, likely with fewer enduring props. A signal processing computer, programmed for audio and/or video recognition, is provided to differentiate between at least the two types with some degree of efficiency, and with a possibly extended sampling time, have a recognition accuracy, such that, when this information is integrated with other available information, a reliable decision may be made. The required level of reliability, of course, will depend on the particular application and a cost-benefit analysis for the required system to implement the decision-making system.

Since the system according to the present invention need not display perfect accuracy, the preferred embodiment according to the present example applies general principles to new situations and receives user or other feedback as to the appropriateness of a given decision. Based on this feedback, subsequent encounters with the same or similar data sets will produce a result which is “closer” to an optimal decision. Therefore, with the aid of feedback, the search criterion would be improved. Thus, a user could teach the interface through trial and error to record the desired broadcast programs. Thus, the presently described recognition algorithms may be adaptive and learning, and need not apply a finite set of predetermined rules in operation. For such a learning task, a neural network processor may be implemented, as known in the art.

The feature extraction and correlation system according to the present invention is shown in FIG. 22. In this figure, the multimedia input, including the audio signal and all other available data, are input in the video input 2201. The video portion is transferred to a frame buffer 2202, which temporarily stores all of the information. All other information in the signal, including audio, VIR, videotext, close caption, SAP (second audio program), and overscan, is preferably stored in a memory, and analyzed as appropriate. The frame buffer 2202 may have an integral or separate prefiltering component 2203. The filtered signal(s) are then passed to a feature extractor 2204, which divides the video frame into a number of features, including movement, objects, foreground, background, etc. Further, sequences of video frames are analyzed in conjunction with the audio and other information, and features relating to the correlation of the video and other information, e.g., correlation of video and audio, are extracted. Other information is also analyzed and features extracted, e.g., audio and close caption. All extracted features relating to the multimedia input are then passed to a transform engine or multiple engines in parallel, 2205. These transform engines 2205 serve to match the extracted features with exemplars or standard form templates in the template database 2206.

It should be noted that even errors or lack of correlation between certain data may provide useful information. Therefore, a mismatch between audio and close caption or audio and SAP may be indicative of useful information. For non-video information, exemplars or templates are patterns which allow identification of an aspect of the signal by comparing the pattern of an unidentified signal with the stored pattern. Thus, the voice patterns of particular persons and audio patterns of particular songs or artists may be stored in a database and employed to identify a source signal.

The transformed extracted features and the templates are then correlated by a correlator or correlators 2207. The parallelization of implementation of the transforms and correlators serves to increase the recognition speed of the device. It should be understood that appropriate systems for parallelization are known in the art. For example, the TMS 320C80, also known as the TI MVP (Texas Instruments multimedia video processor) contains four DSP engines and a RISC processor with a floating point unit on a single die. A board including a TMS 320C80 is available from General Imaging Corp., Billerica Mass., the S/IP80, which may be programmed with ProtoPIPE. In addition, a board including a TMS 320C80 is also available from Wintriss Engineering Corp., San Diego, Calif. Multiple MVP processors may also be parallelized for additional computing power. The MVP may be used to analyze, in parallel, the multimedia input signal and correlate it with stored patterns in a database. In this context, correlation does not necessarily denote a strict mathematical correlation, but rather indicates a comparison to determine the “closeness” of an identified portion of information with an unidentified portion, preferably including a reliability indicator as well. For neural network-based processing, specific hardware accelerators also available, such as from Nestor, Inc. and Intel. Therefore, since there may be multiple recognizable aspects of the unidentified data, and various degrees or genericness of the characteristic recognized, it is preferred that at this initial stage of the recognition process that the output of the correlators 2207 be a data set, e.g. a matrix, series of pointers, or other arrangement, so that sufficient information is available for higher level processing to allow application of an appropriate decision process. Of course, if the characteristic to be detected is simple and well defined, and the decision-making process may be implemented with a simple correlation result, then a complex data set output is not required. In fact, the output of the correlator may have a number of different forms, based on the context of the recognition process.

If, for example, an exact match to an entire frame is sought, partial match information is not particularly useful, and is ignored in this process. (Of course, since the system is “self-leaming”, the processing results may be maintained and analyzed for other purposes). If the system, on the other hand, is analyzing novel data, a full analysis would likely be necessary including partial results and low correlation results.

The outputs of the correlators are input into an adaptive weighing network 2208, to produce a probability of a match between a given feature and a given template. The recognition is completed in an identifier 2209, which produces a signal identifying one or more objects in the video frame input. The identifier 2209 also has an output to the template database 2206, which reinforces the recognition by providing feedback; therefore, if the same object appears again, it will be more easily recognized. The template database 2206 therefore also has an input from the feature extractor 2204, which provides it with information regarding the features recognized. It is also noted that, in addition to allowing recognition, the parallel transform engines 2205, correlators 2207, and adaptive weighing network 2208 also allows the system to ignore features that, though complex, do not aid in recognition.

For example, during dialogue, the soundtrack voice may correlate with the mouth movements. Thus, the mouth movements aid little in recognition, and may be virtually ignored, except in the case where a particular person's mouth movements are distinctive, e.g., Jim Nabors (“Gomer Pyle”), and Tim Curry (“Rocky Horror Picture Show”). Thus, the complexity and parallelism in the intermediate recognition stages may actually simplify the later stages by allowing more abstract features to be emphasized in the analysis. Animation poses a special example where audio and image data may be separated, due to the generally non-physiologic relation between the image and soundtrack.

The pattern recognition function of the present invention could be used, in a VCR embodiment according to the present invention to, e.g., to edit commercials out of a broadcast, either by recognition of characteristics present in commercials, in general, or by pattern recognition of specific commercials in particular, which are often repeated numerous times at various times of the day, and on various broadcast channels. Therefore, the system may acquire an unidentified source signal, which may be, for example, a 30 second segment, and compare this with a database of characteristics of known signals. If the signal does not match any previously known or identified signals, it is then subject to a characterization which may be the same or different than the characterization of the identified signals. The characterizations of the unidentified signal are then compared to characteristics to be recognized. If the unidentified signal meets appropriate criteria, a presumptive generic characterization is made. This characterization is preferably confirmed by a user later, so that a positively identified signal is added to the database of identified signals; however, under certain circumstances no confirmation is required.

Certain media present a recognizable audio or video cue when a commercial break has ended. (E.g. often sports events, such as the Olympic Games, will have theme music or distinctive images). The present device need not respond immediately to such cues, and may incorporate a delay, which would store the information while a decision is being made. In the case of a video tape, the delay may be up to the time between the time of recording and the time of playback. Further, the temporary storage medium may be independent of the pattern recognition system. Thus, a system provided according to the present invention may actually include two independent or semi-independent data streams: the first serving as the desired signal to be stored, retaining visually important information, and the second providing information for storage relating to the pattern recognition system, which retains information important for the recognition process, and may discard this information after the pattern recognition procedure is complete.

A system which provides a plurality of parallel data streams representing the same source signal may be advantageous because is allows a broadcast quality temporary storage, which may be analog in nature, to be separate from the signal processing and pattern recognition stage, which may be of any type, including digital, optical, analog or other known types, which need only retain significant information for the pattern recognition, and therefore may be highly compressed (e.g. lossy compression), and devoid of various types of information which are irrelevant or of little importance to the pattern recognition functions. Further, the temporary storage may employ a different image compression algorithm, e.g. MPEG-4, MPEG-2 or MPEG-1, which is optimized for retention of visually important information, while the recognition system may use a compression system optimized for pattern recognition, which may retain information relevant to the recognition function which is lost in other compression systems, while discarding other information which would be visually important. Advantageously, however, the analysis and content transmission streams are closely related or consolidated, such as MPEG-7 and MPEG-4.

In a particularly advantageous arrangement, the compression algorithm is integral to the recognition function, preparing the data for the pattern matching and characterization, and therefore is optimized for high throughput. According to this embodiment, the initial compression may include redundant or uncompressed information, if necessary in order to achieve real-time or near real-time recognition, and, thus may actually result in a larger intermediate data storage requirement than the instantaneous data presented to the recognition system; however, the term “compression”, in this case, applies to the long term or steady state status of the device, and in a real-time recognition function, the amount of data stored for use in recognition is preferably less than the cumulative amount of data presented, except during the very initial stages of data acquisition and possibly rare peaks.

In the case where a high quality (low loss, e.g. broadcast quality) intermediate storage is employed, after a decision is made as to whether the data should be stored permanently or otherwise further processed or distributed, the data may be transferred to the appropriate system or subsystem of the apparatus. Alternatively, the high quality intermediate storage is retained, and no further processing is performed. In either case, the purpose of this storage is to buffer the source data until the computational latency resolves any decisions which must be made.

According to one aspect of the present invention, the source image may be compressed using the so called “fractal transform”, using the method of Barnsley and Sloan, which is implemented and available as a hardware accelerator in product form from Iterated Systems, Inc., Norcross, Ga., as the Fractal Transform Card (FTC) II, which incorporates eight fractal transform integrated circuit chips, 1 MByte of Random Access Memory (RAM), and an Intel i80960CA-25 P, and operates in conjunction with P.OEM™ (Iterated Systems, Inc., Norcross, Ga.) software, which operates under MicroSoft-Disk Operating System (MS-DOS). FTC-II hardware compression requires approximately 1 second per frame, while software decompression on an Intel 80486-25 based MS-DOS computer, using “Fractal Formatter” software, can be performed at about 30 frames per second, which allows approximately real time viewing. The Fractal Video Pro 1.5 is a video codec for WIN, allowing software only playback at 15–30 fps, 70–150 Kbytes/sec. This is a non-symmetrical algorithm, requiring more processing to compress than to decompress the image. The FTC-IV Compression Accelerator Board is presently available.

This fractal compression method potentially allows data compression of upwards of 2000:1, while still maintaining an aesthetically acceptable decompressed image result. Further, since the method emphasizes structural aspects of the image, as opposed to the frequency decomposition used in DCT methods (JPEG, MPEG), elements of the fractal method could be used as a part of the image recognition system. Of course, it should be appreciated that other fractal processing methods are available and may be likewise employed.

Audio data is also compressible by means of fractal transforms. It is noted that the audio compression and image recognition functions cannot be performed on the FTC-II board, and therefore an alternate system must be employed in order to apply the pattern recognition aspects of the present invention. It should also be noted that an even more efficient compression-pattern recognition system could be constructed by using the fractal compression method in conjunction with other compression methods, which may be more efficient under certain circumstances, such as discrete cosine transform (DCT), e.g. JPEG or modified JPEG or wavelet techniques. Fractal compression systems are also available from other sources, e.g. the method of Greenwood et al., Netrologic Inc., San Diego, Calif. See also, Shepard, J. D., “Tapping the Potential of Data Compression”, Military and Aerospace Electronics, May 17, 1993, pp. 25–27.

A preferred method for compressing audio information includes a model-based compression system. This system may retain stored samples, or derive these from the data stream. The system preferably also includes high-level models of the human vocal tract and vocalizations, as well as common musical instruments. This system therefore stores information in a manner which allows faithful reproduction of the audio content and also provides emphasis on the information-conveying structure of the audio signal. Thus, a preferred compression for audio signals retains, in readily available form, information important in a pattern recognition system to determine an abstract information content, as well as to allow pattern matching. Of course, a dual data stream approach may also be applied, and other known compression methods may be employed.

Because of the high complexity of describing a particular signal pattern or group of audio or image patterns, in general, the system will learn by example, with a simple identification of a desired or undesired pattern allowing analysis of the entire pattern, and extraction of characteristics thereof for use in preference determination.

Barnsley and Sloan's method for automatically processing digital image data consisting of image information, disclosed in U.S. Pat. Nos. 5,065,447 and 4,941,193, both expressly incorporated herein by reference, consists of the steps of storing the image data in the data processor, then generating a plurality of uniquely addressable domain blocks from the stored image data, each of the domain blocks representing a different portion of the image information such that all of the image information is contained in at least one of the domain blocks. A plurality of uniquely addressable mapped range blocks corresponding to different subsets of the stored image data are created, from the stored image data, with each of the subsets having a unique address. This step includes the substep of executing, for each of the mapped range blocks, a corresponding procedure upon the one of the subsets of the stored image data which corresponds to the mapped range block. Unique identifiers are then assigned to corresponding ones of the mapped range blocks, each of the identifiers specifying for the corresponding mapped range block a procedure and a address of the corresponding subset of the stored image data. For each of the domain blocks, the one of the mapped range blocks which most closely corresponds according to predetermined criteria is selected. Finally, the image information is represented as a set of the identifiers of the selected mapped range blocks. This method allows a fractal compression of image data. In particular, Drs. Barnsley and Sloan have optimized the match of the domain blocks with the mapping region by minimizing the Hausdorff distance. A decompression of the data precedes analogously in reverse order starting with the identifiers and the mapping regions to produce a facsimile of the original image. This system is highly asymmetric, and requires significantly more processing to compress than to decompress. Barnsley and Sloan do not suggest a method for using the fractal compression to facilitate image recognition, which is a part of the present invention.

Basically, the fractal method proceeds from an understanding that real images are made up of a plurality of like subcomponents, varying in size, orientation, etc. Thus, a complex block of data may be described by reference to the subcomponent, the size, orientation, etc. of the block. The entire image may thus be described as the composite of the sub-images. This is what is meant by iterative function systems, where first a largest block is identified, and the pattern mapping is repetitively performed to describe the entire image.

The Iterated Systems, Inc. FTC-II or FTC-IV board, if applied as a part of a system according to the present invention, is preferably used in conjunction with a frame-grabber board, such as Matrox, Quebec, Canada, Image-LC board, or a Data Translation DT1451, DT2651, DT2862, DT2867, DT2861 or DT2871, which may perform additional functions, such as preprocessing of the image signal, and may be further used in conjunction with an image processing system, such as the Data Translation DT2878. Of course, it should be understood that any suitable hardware, for capturing, processing and storing the input signals, up to and including the state of the art, may be incorporated in a system according to the present invention without exceeding the scope hereof, as the present invention is not dependent on any particular subsystem, and may make use of the latest advances. For example, many modern systems provide appropriate functionality for digital video capture, either uncompressed, mildly compressed, or with a high degree of compression, e.g., MPEG-2.

The Texas Instruments TMS320C80 provides a substantial amount of computing power and is a preferred processor for certain computationally intensive operations involving digital signal processing algorithms. A system employing a parallel TMS 320C40 processors may also be used. The Intel Pentium series (or related processors from AMD, National Semiconductor, or other companies), DEC/Compaq Alpha, SPARC, or other processors intended for desktop computing may, either individually or in multiprocessor configurations, be used to process signals.

A pattern recognition database system is available from Excalibur Technologies, San Diego, Calif. Further, IBM has had pattern recognition functionality available for its DB/2 database system, and has licensed Excalibur's XRS image retriever recognition software for DB/2. See, Lu, C., “Publish It Electronically”, Byte, September 1993, pp. 94–109. Apple Computer has included search by sketch and search by example functions in PhotoFlash 2.0. See also, Cohen, R., “FullPixelSearch Helps Users Locate Graphics”, MacWeek, Aug. 23, 1993, p. 77.

Image processing hardware and systems are also available from Alacron, Nashua N.H.; Coreco, St. Laurent, Quebec; Analogic, and others.

A fractal-based system for real-time video compression, satellite broadcasting and decompression is also known from Iterated Systems, Inc. and Entertainment Made Convenient², Inc. (EMC²). In such a system, since the compressed signal is transmitted, the remote receiving system need not necessarily complete decompression prior to the intelligent pattern recognition function of the present invention. This system also incorporates anti-copy encryption and royalty and accounting documentation systems. It is noted that the EMC² system does not incorporate the intelligent features of the present invention.

A preferred fractal-based system according to the present information provides the source data preprocessed to allow easy and efficient extraction of information. While much precharacterization information may be provided explicitly, the preferred system allows other, unindexed information to also be extracted from the signal. Further, the preferred system provides for an accounting system which facilitates pay-per-view functions. Thus, the interface of the present invention could interact with the standard accounting system to allow royalty-based recording or viewing, and possibly implement a serial-copy recording prevention system. Prior art systems require a user to explicitly select a program, rather than allow an intelligent system to assist in selection and programming of the device. The EMC² system is described in “EMC² Pushes Video Rental By Satellite”, Electronic Engineering Times, Dec. 2, 1991, p. 1, p. 98. See also, Yoshida, J., “The Video-on-demand Demand”, Electronic Engineering Times, Mar. 15, 1993, pp. 1, 72.

Fractal techniques may be used to store images on a writable mass storage medium, e.g. CD-ROM compatible. The present system may thus be used to selectively access data on the CD-ROM by analyzing the images, without requiring full decompression of the image data.

Wavelets hold promise for efficiently describing images (i.e., compressing the data) while describing morphological features of the image. However, in contrast to wavelet transforms which are not intended to specifically retain morphological information, the selection of the particular wavelet and the organization of the algorithm will likely differ. In this case, the transform will likely be more computationally complex and therefore slower, while the actual compression ratios achieved may be greater.

Thus, one embodiment of the device according to the present invention may incorporate a memory for storing a program, before being transferred to a permanent storage facility, such as tape. Such a memory may include a hard disk drive, magnetic tape loop, a rewritable optical disk drive, or semiconductor memories, including such devices as wafer scale memory devices. This is shown diagrammatically as the intermediate storage 2210 of FIG. 22. The capacity of such a device may be effectively increased through the use of image data compression, which may be proprietary or a standard format, i.e. MPEG-1, MPEG-2 (Motion Picture Experts Group standard employing DCT encoding of frames and interframe coding), MPEG-4 (Motion Picture Experts Group standard employing DCT encoding of frames and interframe coding, as well as model-based encoding methods) JPEG (Joint Photographic Experts Group standard employing DCT encoding of frames), Px64 (Comité Consultatif International des Telegraph et telephone (International telegraph and telephone consultative committee) (CCITT) standard H.261, videoconferencing transmission standard), DVI (Digital Video Interactive), CDI (Compact Disk Interactive), etc.

Standard devices are available for processing such signals, available from 8×8, Inc., C-Cube, Royal Philips Electronics (TriMedia), and other companies. Image processing algorithms may also be executed on general purpose microprocessor devices.

Older designs include the Integrated Information Technology, Inc. (IIT, now 8×8, Inc.) Vision Processor (VP) chip, Integrated Information Technology Inc., Santa Clara, Calif., the C-Cube CL550B (JPEG) and CL950 (MPEG decoding), SGS-Thompson STI3220, STV3200, STV3208 (JPEG, MPEG, Px64), LSI Logic L64735, L64745 and L64765 (JPEG) and Px64 chip sets, and the Intel Corp. i750B DVI processor sets (82750PB, 82750 DB). Various alternative image processing chips have been available as single chips and chip sets; in board level products, such as the Super Motion Compression and Super Still-Frame Compression by New Media Graphics of Billerica, Mass., for the Personal Computer-Advanced technology (PC-AT, an IBM created computer standard) bus; Optibase, Canoga Park, Calif. (Motorola Digital Signal Processor (DSP) with dedicated processor for MPEG); NuVista+from Truevision (Macintosh video capture and output); New Video Corp. (Venice, Calif.) EyeQ Delivery board for Macintosh NuBus systems (DVI); Intel Corp. ActionMedia II boards for Microsoft Windows and IBM OS/2 in Industry Standard Adapter (ISA, the IBM-PC bus standard for 8 (PC) or 16 bit (PC-AT) slots); Micro Channel Architecture (MCA) (e.g., Digital Video Interactive (DVI), Presentation Level Video (PLV) 2.0, Real Time Video (RTV) 2.0) based machines; and as complete products, such as MediaStation by VideoLogic.

Programmable devices, including the Texas Instruments TMS320C80 MVP (multimedia video processor) may be used to process information according to standard methods, and further provide the advantage of customizability of the methods employed. Various available DSP chips, exemplary board level signal processing products and available software are described in more detail in “32-bit Floating-Point DSP Processors”, EDN, Nov. 7, 1991, pp. 127–146. The TMS320C80 includes four DSP elements and a RISC processor with a floating point unit.

It is noted that the present interface does not depend on a particular compression format or storage medium, so that any suitable format may be used. The following references describe various video compression hardware: Kim, Y., “Chips Deliver Multimedia”, Byte, December 1991, pp. 163–173; and Donovan, J., “Intel/IBM's Audio-Video Kernel”, Byte, December, 1991, pp. 177–202.

It should also be noted that the data compression algorithm applied for storage of the received data may be lossless or lossy, depending on the application. Various different methods and paradigms may be used. For example, DCT (discrete cosine transform) based methods, wavelets, fractals, and other known methods may be used. These may be implemented by various known means. A compressed image may also be advantageously used in conjunction with the image recognition system of the present invention, as described above. In such a case, the compression system would retain the information most important in the recognition function, and truncate the unimportant information.

A further method of performing pattern recognition, especially of two dimensional patterns, is optical pattern recognition, where an image is correlated with a set of known image patterns represented on a hologram, and the product is a pattern according to a correlation between the input pattern and the provided known patterns. Because this is an optical technique, it is performed nearly instantaneously, and the output information can be reentered into an electronic digital computer through optical transducers known in the art. Such a system is described in Casasent, D., Photonics Spectra, November 1991, pp. 134–140. See also references cited therein.

These optical recognition systems are best suited to applications where an uncharacterized input signal frame is to be compared to a finite number of visually different comparison frames (i.e., at least one, with an upper limit generally defined by the physical limitations of the optical storage media and the system for interfacing to the storage media), and where an optical correlation will provide useful information. Thus, if a user wished to detect one of, e.g., “David Letterman”, “Jay Leno”, or “David Koppel”, a number of different planar views, or holograms in differing poses, of these persons would be formed as a holographic correlation matrix, which could be superimposed as a multiple exposure, stacked in the width dimension, or placed in a planar matrix, side by side. The detection system produces, from the uncharacterized input image and the holographic matrix, a wavefront pattern that is detectable by photonic sensors.

It is preferred that if multiple holographic images of a particular characterization are employed, that they each produce a more similar resulting wavefront pattern than the holographic images of other characterizations, in order to enhance detection efficiency. The optical pattern recognition method is limited in that a holographic image must be prepared of the desired pattern to be detected, and that optically similar images might actually be of a different image, if the differences are subtle. However, this method may be used in conjunction with electronic digital pattern recognition methods, to obtain the advantages of both. Methods are also known to electronically write an image to a holographic storage medium, thereby facilitating its use in a general-purpose image recognition system. Of course, the system may also be used to identify talk show guests, such as “Richard Gere” or “Cindy Crawford”, or these same individuals in other contexts.

If image compression is used, once an image is compressed, it need not be decompressed and returned to pixel, NTSC or other standard transmission or format for storage on tape, and thus the compressed image information may be stored in the same format as is present in the temporary storage medium. Thus, the block labeled intermediate processing 2211 of FIG. 22 shows that the intermediate storage need not retain the information as received from the frame buffer 2202, and in fact, may prepare it for the feature extractor 2204. In addition, the storage medium itself need not be normal videotape (S-VHS, VHS, Beta, 8 mm, Hi-8) and may be an adapted analog storage technique or a digital storage technique. Various magneto-optical recording techniques are known, which can store between 128 MB (3½″) and around 5 GB (11″), uncompressed, which might be suitable for storing compressed digital or analog information. Multilayer CD-ROM and short wavelength (e.g., blue) laser systems allow storage densities of about 3.5 to 10 Gbytes per disk, allowing storage of over two hours of MPEG-2 encoded video.

It is also noted that the present technology could also be applied to any sort of mass storage, such as for a personal computer. In such a case, a characteristic of the computer file, which is analogous to the broadcast program in temporary storage of a VCR, is classified according to some criteria, which may be explicit, such as an explicit header or identifying information, or implicit, such as a document in letter format, or a memorandum, as well as by words and word proximity. In particular, such a recognition system could differentiate various clients or authors based on the content of the document, and these could be stored in different manners. The text analysis system of a text-based computer storage system is analogous to the program classification system of the VCR embodiment of the present invention. However, there is a further analogy, in that the VCR could incorporate optical character recognition of text displayed in the program material, employ voice recognition, or directly receive text information as a part of a closed caption or videotext system. Thus, the VCR device according to the present invention could recognize and classify programs based on textual cues, and make decisions based on these cues. This might also provide a simple method of discriminating program material, for example, if a commercial does not include close caption or Second Audio Program (SAP), while the desired program does, or vice versa, then a commercial could be discriminated from a program with very little computational expenditure.

EXAMPLE 7 VCR Interface

A particular VCR interface system according to one aspect of the present invention includes an internal clock, four program memory, and the capability to display a graphical color interface. By providing the user with the aforementioned features, this design is a unique implementation for an instrument to be used for programming an event driven controller via an interactive display. All information that the user needs is displayed on the screen to avoid or minimize the unnecessary searching for information. This information includes the current date and current time.

A simulation of the AKAI Inc. VCR VS303U (on-screen programming) and the interface of the present invention, were tested to evaluate users' performances. The AKAI interface of the prior art, hereinafter referred to as the prior art interface, was chosen because users made the fewest errors while using this machine, and no user quit while programming, as compared to three other VCRs tested, a Panasonic (made by Matsushita, Inc.) PV4962 (Bar Coder), an RCA brand (formerly Radio Corporation of America, Inc.) VKP950 (on-screen programming), Panasonic brand (made by Matsushita Inc.) PV4700 (Display Panel).

The present embodiment was constructed and tested using HyperPAD™, a rapid prototyping package for an IBM-PC Compatible Computer. It is, of course obvious that the present embodiment could be incorporated in a commercial VCR machine by those skilled in the art, or be implemented on many types of general purpose computers with output screens which allow on-screen feedback for the programming operation. Further, the system of the present embodiment can include a remote-control device which communicates with a VCR through an infrared beam or beams, and can thus exert control over an infrared remote controlled VCR, or translate the programming information and communicate through an infrared remote control, using the standard type infrared transmitter.

An IBM PC-AT compatible (MS-DOS, Intel 80286-10 MHz) computer was used to test the two simulations. In order to simulate the use of a remote control device in programming the VCR, an infrared device made by NView™ was attached to the computer. This device came with a keyboard that was used to “teach” a Memorex™ Universal Remote so that the desired actions could be obtained. By using a universal remote, the computer could be controlled by using a remote control.

The present embodiment incorporates a mouse input device. It is understood that a small trackball with a button for selection, mounted on a remote control may also be employed, and may be preferable in certain circumstances. However, a computer mouse is easily available, and the mouse and trackball data are essentially similar for the type of task implemented by the user, with trackball performance being slightly faster. For daily use on a VCR however, a trackball would be a more preferable input device because it does not require a hard, flat surface, which is not always available to a user when programming a VCR, such as in the situation where a person is watching television while sitting in a chair or sofa.

A Genius™ Mouse was used as the input device in the prototype of the interface of the present invention. With the mouse, the user could view all of the choices at once on the display screen, and then make a selection from the items on the screen by moving the cursor and then pressing the left mouse button.

The interface of the present example focuses on attending to the user's needs, and the interface must be modified for each application. By reducing the searching, learning times, and entry times, the mental load is also minimized. Some tradeoffs are necessary as a result of subjective and objective data. Because of the difficulty in optimizing a single interface design for all levels of users, a menu system was used in an attempt to satisfy all these user types.

The interface of the present example reduced the number of incorrect recordings by 50%. The severity of the errors is unimportant here because one wrong entry will cause an irretrievable mistake and the user will not record the intended program. One study reported that faulty inputs, which lead to missing the program, can be reported by almost every present day owner of a VCR.

EXAMPLE 8 Programmable Device Interface

It is also noted that the interface of the present invention need not be limited to audio-visual and multimedia applications, as similar issues arise in various programmable controller environments. Such issues are disclosed in Carlson, Mark A., “Design Goals for an Effective User Interface”, Electro/82 Proceedings, 3/1/1–3/1/4; Kreifeldt, John, “Human Factors Approach to Medical Instrument Design”, Electro/82 Proceedings, 3/3/1–3/3/6; Wilke, William, “Easy Operation of Instruments by Both Man and Machine”, Electro/82 Proceedings, 3/2/1–3/2/4; Green, Lee, “Thermo Tech: Here's a common sense guide to the new thinking thermostats”, Popular Mechanics, October 1985, 155–159; Moore, T. G. and Dartnall, “Human Factors of a Microelectronic Product: The Central Heating Timer/Programmer”, Applied Ergonomics, 1983, Vol. 13, No.1, 15–23; and “The Smart House: Human Factors in Home Automation”, Human Factors in Practice, December 1990, 1–36.

This generalized system is shown in FIG. 23, in which the sensor array 2301 interfaces with a microprocessor 2302 with a serial data port 2302 a, which transmits sensor data to a control 2303. The control 2303 further interfaces or includes a data pattern recognition system 2304 and an interface and programming console 2305 according to the present invention, using the aforementioned intelligent features and adaptive pattern recognition techniques. The control 2203 controls the plant 2306, which includes all the controlled actuators, etc.

EXAMPLE 9 Adaptive Graphic Interface

A “smart screen” aspect according to the present invention is further explored in the present example. This aspect of the present invention allows the interface to anticipate or predict the intent of the user, to provide, as a default user choice, the most likely action to be taken by the user of the programmable device as a default, which may be either accepted or rejected by the user, without inordinate delay to the user. The intelligent selection feature may also automatically choose an option and execute the selected option, without further intervention, in cases where little or no harm will result. Examples of such harm include a loss of data, a substantial waste of the user's time and an inappropriate unauthorized allocation of computational resources.

When a user regularly applies the VCR device, for example, to record a particular television show which appears weekly on a given television channel, at a given time, on a given channel, such an action could be immediately presented to the user as a first option, without forcing him to explicitly program the entire sequence. Likewise, if the user has already entered such a command, the presented choices could include a second most likely selection, as well as the possibility of canceling the previously entered command.

Further, if an entire television programming guide for a week or month is available as a database, the interface could actively determine whether the desired show is preempted, a repeat (e.g., one which has been previously recorded by the system), changed in time or programming slot, etc. Thus, the interface could present information to the user, of which he might not be aware, and/or predict an action based on that information. Such a device could, if set in a mode of operation that allows such, automatically execute a sequence of instructions based on a predicted course of action. Thus, if a user is to be absent for a period, he could set the machine to automatically record a show, even if the recording parameters are not known with precision at the time of setting by the user. Of course, this particular embodiment depends on the availability of a database of current broadcast schedules, however, such a database may generally be available, e.g., in an on-line database.

Such an on-line database system of known type may be used and need not be described in detail herein. Alternately, a printed schedule of broadcasts may be scanned into a computer and the printed information deciphered (e.g., OCR) to gain access to a database. Other methods may also be used to access scheduling information, e.g. access channels on cable systems, as well as other broadcast information identifying future and imminent programming. Together, these methods allow semiautonomous operation, guided by programming preferences rather than explicit programs, where such explicit instruction is absent.

The smart screens according to the present invention may be implemented as follows. The controller may be, for example, an Apple Power Macintosh 8100/110 AV computer, operating under Macintosh 7.5 operating system. The Hypercard™ 2.3 software may be used to implement the screen interface, which incorporates the above-described features, which is generally compatible with the Hyperpad software described above. HyperCard™ is mentioned due to its capabilities to reference external programs, thus allowing interfacing to various software and hardware devices. A more global scripting language, such as Frontier by UserLand Software Inc., may also be used, especially where low level hardware control of interfaced devices, such as a VCR, multimedia adapter, or the like is desired. Apple Applescript may also be used. The Quicktime format may be used to store and recall data, however, many acceptable formats exist. The input device is an Apple Desktop Bus (ADB) mouse (Apple Computer Inc., Cupertino, Calif.), and the output display is an 8 bit or 24 bit graphics color adapter connected to, e.g., a 14″ color monitor. In addition, various parameters concerning the use of the interface are stored in the computer's memory, and a non-volatile mass storage device, such as a hard disk drive, or Electrically Erasable Programmable read Only Memory (EEPROM) or Erasable Programmable Read Only Memory (EPROM), as well as battery backed Random Access Memmory (RAM) could also be used.

A more modern implementation might employ, for example, a single or dual Pentium II 450 MHz workstation, running Microsoft Windows NT 4.0 (or Windows 2000, when available). The hardware is a matter of choice, including memory, monitor, pointing device, graphic display card, video capture card, mass storage options, and the like. Preferably, a hardware codec is provided, for example a Media 100, Inc. Broadway device. The software may be, for example. Microsoft Visual Basic 5.0 or other suitable development language.

Intel Pentium-based platforms may also be used, preferably in IBM-PC compatible implementations. Intel 80860 and/or Intel 80960 processor platforms may also be used.

Alternatively, other Apple Power PC, Macintosh (MC680X0 series) or IBM Power PC implementation may be used, providing the advantage of increased processing power over Motorola 680X0 derivatives. The specific Power PC employed may be any version, including desktop system versions available from Apple and IBM and embedded versions from IBM and Motorola. These Power PC processors may also be provided in a parallel processing implementation. Further, custom implementations of Power PC hardware optimized for the relevant computational tasks may be employed.

Of course, other systems, including DEC Alpha and HP 9000 systems may also be employed, as well as SPARC, MIPS, and other available RISC systems. While RISC systems, possibly supplemented with DSP hardware, are presently preferred because of their efficiency in executing the pattern recognition tasks, Complex Instruction Set Computer (CISC)., hybrid and other known processing systems may be employed. The Texas Instruments TMS320C80 combines a Reduced Instruction Set Computer (RISC) processor, Arithmetic logoc Unit (ALU) and four DSP processors on a single chip, and is therefore a preferred processor for implementing various aspects of the system, especially mathematical processing including DCT and correlations.

According to the present invention, the interface may perform comparatively simple tasks, such as standard graphic user interface implementation with optimized presentation of screen options, or include more complex functionality, such as pattern recognition, pattern matching and complex user preference correlations. Therefore, hardware requirements will range from basic 68040, 80486, Pentium, Power PC, MIPS, SPARC, Digial Equipment Corp. (DEC, now Compaq Computer Corp.) Alpha, or other microprocessors which are used to perform visual or audio interface functions, to much special purpose processors for implementation of complex algorithms, including mathematical, neural network, fuzzy logic, and iterated function systems (fractals).

It should be noted that, while many aspects of the intelligent interface according to the present invention do not require extremely high levels of processing power, and therefore may be provided with inexpensive and commonly available computing hardware, other aspects involve complex pattern recognition and advantageously employ powerful processors to achieve a short processing latency. Both simple and complex interface systems, however, are included within the scope of the present invention. Processing may be distributed in different fashions, so that complex functionality may be implemented with relatively simple local hardware, with a substantial amount of required processing for a high level of functionality performed centrally, and for a large number of users.

From the stored information regarding the prior use of the interface by the user, including prior sessions and the immediate session, and a current state of the machine (including a received data stream and information relating to the data stream previously stored), a predicted course of action or operation may be realized. This predicted operation is, in the context of the current user interface state, the most probable next action to be taken by the user.

The predicted operation is based on: the identity of the user, if more than one user operates the interface and machine, the information already entered into the interface during the present programming session, the presently available choices for data entry, settings for the use of the machine, which may be present as a result of a “setup” operation, settings saved during a prior session, and a database of programming choices. In the case of a HyperCard script, the interface software calls another program which has access to the necessary data in the memory, as well as access to any remote database which may be necessary for implementation of the function. Using a predictive technology, such as Boolean logic, fuzzy logic, neural network logic, or other type of artificial intelligence, a most probable choice may be presented to the user for his approval, or another alternative choice may be selected. Further, a number of most probable choices may be presented simultaneously or in sequence, in order to improve the probability that the user will be immediately or quickly presented with an acceptable choice. If multiple choices are presented, and there is limited room on the display, two (or more) similar choices may be merged into a single menu selection, which may be resolved in a secondary menu screen. e.g. a submenu or dialog box.

FIG. 24 shows a system for correlating a user's preferences with a prospective or real-time occurrence of an event. The input device 2401, which is a remote control with a pointing device, such as a trackball, provides the user's input to the control 2402. The program is stored in a program memory 2403, after it is entered. The control 2402 controls a plant 2404, which is a VCR. The control also controls an on-screen programming interface 2405, through which the user interactively enters the program information. Each program entry of the user is submitted to the user history database and preferences module 2406, which may also receive explicit preference information, input by the user through the input device 2401. The prospective and real time event characterization unit 2407 uses any and/or all relevant information available in order to determine the character of a signal input, which is a video signal, from the signal receiver 2408. A signal analyzer 2409 provides a preliminary analysis and characterization of the signal, which is input to the prospective and real time event characterization unit 2407. The prospective and real time event characterization unit 2407 also interacts and receives an input from a telecommunication module 2410, which in turn interacts and receives information from an on-line database 2411. A user preference and event correlator 2412 produces an output relating to a relatedness of an event or prospective event and a user preference. In the event of a high correlation or relatedness, the control 2402 determines that the event or prospective event is a likely or most likely predicted action. The prospective event discussed above refers to a scheduled event, which is likely to occur in the future. The characterization unit also has a local database 2413 for storing schedule information and the like.

In the particular context of a videotape, one consideration of the user is the amount of time remaining on the tape. Generally, users wish to optimally fill a tape without splitting a program, although the optimization and non-splitting parameters may vary between users. Therefore, the length of the tape and the amount and character of other items on the tape are also factors to be employed in determining a most desired result. With respect to this issue, the interface may maintain a library function which allows the identification of a partially filled tape for recording under given circumstances. The interface may also optimize a playback by selecting a tape containing a desired sequence of materials.

The intelligent interface may also be used as a part of an educational system, due to its ability to adapt to the level of the user and dynamically alter an information presentation based on the “user level”, i.e. the training status of the user, and its ability to determine areas of high and low performance. Likewise, the intelligent interface according to the present invention may also be used in a business environment for use by trained individuals who require relatively static software interface design for consistence and “touch typing” with memorized keystroke or mouse click sequences. In this case, the intelligent functionality is segregated into a separate user interface structure, such as an additional “pull down menu” or other available screen location. While the interface always monitors user performance, the impact of the analysis of the user is selectively applied. User analysis may also be used for performance evaluation according to an objective criteria, based on continuous monitoring. In a network environment, user profile and evaluation may be made portable, stored so as to be accessible from any networked device the user may interact with, from office computers to thermostats to photocopying machines to coffee machines.

EXAMPLE 10 Intelligent Adaptive VCR Interface

A user interacting with the device intends to record a particular program, “Married With Children” (Fox, Sunday, 9:00 p.m., etc.) on its ever occurrence. This intent, however, is to provide a full library of episodes, and not to duplicate episodes. The particular program is subject to the occurrence of reruns, syndicated distribution, time shifting of performance, preview scenes and advertisements. Further, various actors appearing in the particular program also appear in other capacities and roles on television. Therefore, after this intent is elucidated, the interface scans available directories of programming to determine when “Marries With Children” will be broadcast. In addition, to the extent possible, all channels may be monitored, in the event that the directories or erroneous or incomplete.

It is noted that the interface may be quite effective if it is used for a number of applications, such as television, radio, desktop computer, and even kitchen and HVAC system. For example, preferences for processing MTV or other music video information may be directly relevant to processing of radio or other music reproduction devices, and vice versa.

At some point in the process, preferably prior to substantive programming input, the interface performs a self-diagnostic check to determine whether the machine is set up and operating correctly. This would include a determination of whether the clock has been set and thereafter operating continuously. Of course, the clock could have, in practice, a battery to minimize the occurrence of problems relating to clock function. The interface would then, if the clock is not properly set, and if there is no telecommunication or other external means for automatically determining the exact time, present the user with a menu selection to set the proper time. Of course, if the correct time is available to the apparatus in some form, this could be automatically obtained, and the internal clock updated, without intervention. These same sources may be used to verify the accuracy of an internal clock. Further, if a reliable external clock system is available, an internal clock may be dispensed with or ignored. Time may also be inferred based on the regular schedules of broadcasts, e.g., the 11:00 p.m. news begins at 11:00 p.m. If the user does not have access to a source of the exact time, the step of correcting the time may be deferred, although at some point the user should be reminded to verify the clock information. The user may thus be able to override a machine-generated request or attempt to correct the time data.

If the machine has access to an external source of the exact time, it would then preferably access this source first. Such sources of exact time include a telephone connection to a voice line which repeats the time. The computer would then perform a speech recognition algorithm which would be used to determine the time. Such a speech recognition algorithm could also be used as a part of the user interface for other purposes, i.e. a speech recognition system is not supplied solely for obtaining time information. Alternatively, a modem or communication device could be used to obtain the time in digitally coded form over a network, which would alleviate the need for speech recognition capabilities for this function. An on-line connection could also be used in order to obtain information concerning television scheduling.

A further method for obtaining accurate time information is to access a video signal which contains the desired time information. For example, many cable broadcasting systems have a channel which continuously broadcasts the time in image form. The interface tunes this channel, and acquires a representation of the screen image, thereafter performing a character recognition algorithm to capture the time information. This character recognition algorithm could also be used to obtain or capture information regarding programming schedules, stock prices, and other text information which may appear on certain cable broadcast channels.

Thus, the interface, in obtaining necessary information, employs such available data source access methods as speech recognition, character recognition, digital telecommunication means, radio wave reception and interpretation, and links to other devices.

In interacting with the apparatus, the user first identifies himself/herself to the machine, which can occur in a number of ways. This step may be dispensed with, or at least trivialized, if only one user regularly interacts with the apparatus. Otherwise, such identification may be important in order to maintain the integrity of the user profiles and predictive aspects of the interface. An radio frequency transponder (RF-ID), infrared transponder (IR-ID) system may automatically determine the user based on a devices, which may be concealed in a piece of jewelry or wristwatch. The user may also be identified by voice pattern recognition, speaker independent voice recognition, video pattern recognition, fingerprint, retinal scan, or other biometric evaluation. An explicit entry of the user identity may also be employed, wherein the user types his/her name on a keyboard or selects the name or unique identifier from a “pick-list”. The interface, upon identifying the user, retrieves information regarding the user, which may include past history of use, user preferences, user sophistication, patterns of variation of user, which may be based on, e.g., time, mood, weather, lighting, biometric factor or other factors.

Thus, after completing system diagnostics, including the time-check function referred to above, the system next determines or predicts the desired function of the user. In this regard, if more than one user has access to the system, the user identifies himself to the interface, in a user identification step 1701 or an analogous action, which may be a coded entry, or a selection from the menu. If the interface has voice recognition capability, then the user may be recognized by his voice pattern, or merely by stating his name. The interface then accesses the memory for a profile of the past use of the machine by the user, which may include the entire prior history, relevant abstracts of the history, or derived user preferences, as shown in the personalized startup based on user profile step 1702, which information is also stored and used in the past user history determining element 2107. These choices differ in the amount of storage necessary in order to retain the desired information.

Thus, if the user has only used the VCR to record, e.g., the National Broadcasting Company (NBC) 11 o'clock news, i.e., record all days from 11:00 p.m. to 11:30 p.m. on NBC, in the past, the most likely current predicted choice would be the NBC 11 o'clock news. If the interface were to present a number of choices, having lower probability, then it interprets the recording history to be “news” based on a database of broadcast information. Therefore, a prediction of lower probability would be American Broadcasting Company (ABC) or Central Broadcasting Company (CBS) news at, e.g., 11:00 p.m., and the NBC news at, e.g., 5:00 p.m. In a cable television system, there may be a number of NBC affiliated news alternatives, so that these alternatives may be investigated first before other networks or the like are presented as likely choices. In addition, where a video feed is unavailable, a text feed from the internet or an on-line service may be acquired as a probable alternative.

Thus, a number of likely choices, based on intelligently determined alternatives, as well as adaptation based on determined user preferences, are initially presented to the user, along with a menu selection to allow rejection of these predicted choices. In this case, the user selects the “reject” selection, and the system presents the user with a next predicted desired menu choice. Since the user history, in this case, does not provide for another choice of particularly high probability, the user is prompted to explicitly choose the program sequence by day, time, channel, and duration. The user then enters the starting time for recording according to the methods described above. The interface then searches its databases regarding the user and broadcast listings to present a most likely choice given that parameter, as well as all available alternatives. In this case, the user history is of little help, and is not useful for making a prediction. In other cases, the system uses its intelligence to “fill in the blanks”, which could, of course, be rejected by the user if these are inaccurate or inappropriate. The most likely choices are then those programs that begin at the selected time. If the user had input the channel or network, instead of starting time, then the presented choices would be the broadcast schedule of the channel, e.g. channel 5 or Fox, for the selected day.

The user then selects one of the available choices, which completes the programming sequence. If no database of broadcasts is available, then the user explicitly defines all parameters of the broadcast. When the programming is completed, the interface then updates its user database, prompts the user to set the VCR to record, by, e.g., inserting a blank or recordable tape.

If the predicted desire of the user is of no help, or the user seeks to explicitly program the system, a manual program entry system is available. Where there is no useful prediction of the user, the interface may request a training session, which may be a general inquiry, or specifically directed to immediately forthcoming broadcasts, or both.

In this case, after a failure to predict a desired program, the user then proceeds to explicitly program the VCR interface to record “Married with Children” on Fox at 9:00 p.m. on. Sunday evening. If a database is available, it might also show that “Married with Children” is also syndicated in re-runs, and therefore various episodes may be available on other channels at other times. Thus, during the subsequent session, both the premier showing and re-run of “Married With Children” would be available predicted choices, along with the 11 o'clock News on NBC.

The user having demonstrated a preference for “Married with Children”, the interface then characterizes the program. This includes, for example, a characterization of the soundtrack, the background, foreground, actors and actresses present, credits, etc. The interface then attempts to correlate the features present in the reference selection with other available selections. This comparison may be with a preformed database, providing immediate results, or prospectively, after entry of the reference selection. Of course, a number of correlation functions may proceed simultaneously, and various choices may be merged to form a compound reference selection, any ambiguity in which to be later resolved. Further, as various “episodes” of the reference selection occur, the system appends and integrates the most recent occurrence with the stored reference information, thus updating the reference database.

When an occurrence is identified, it is immediately buffered, until such time as the particular episode may be compared against previously stored episodes. If two identical broadcasts occur simultaneously, one may be selected, i.e., the one with the best reception. When the episode is identified, if it is new, the buffered broadcast information is permanently stored; if it is previously stored, the buffer is flushed and the occurrence is further ignored as a “hit”. Since the apparatus is now not responding to a direct request, it may then perform various housekeeping functions, including updating databases of broadcasts and the like. This is because, although the apparatus is preferably highly trained upon manufacture, a large number of new broadcasts are always being created and presented, so that the apparatus must constantly maintain its “awareness” of data types and trends, as well as update its predicted preferences of the user(s).

Based on input from the user, other programming including the same actors and/or actresses may be processed, e.g., recorded. For example, Katey Segal periodically appears on “Jay Leno” as a musical guest, and therefore may be recorded in these appearances.

EXAMPLE 11 Intelligent Adaptive VCR Interface

Another example of the use of the present programming system allows a hybrid request which does not correspond to any single broadcast schedule entry. In this case, if the user instead wishes to record weather reports on all channels, the interface may be of further help. The interface controls a plurality of tuner elements 2502 of a video signal reception device 2501, so that a plurality of broadcasts may be simultaneously received. Using the mass storage and possibly image data compression described above, a plurality of broadcasts may also be recorded simultaneously in the intermediate storage 2503. The mass storage may be multiple VCRs, optical storage, magnetooptical storage, magnetic storage including disk (e.g. single disks, multimedia compatible disks, RAID, etc.) tape (QIC, 8 mm, 4 mm, etc.). Preferably, the archival recording medium is recordable DVD or possibly recordable CD-ROM.

The optical recording tape produced by ICI, Inc., or other card or tape optical storage medium might also be a useful storage medium for large volumes of data, as might be generated by recording multiple video signals. The known implementations of the ICI product system best suited for commercial or industrial use and not for individual consumer use.

In any case, the interface 2506 accesses its associated database 2413 to determine, at a given time, which channels are broadcasting “news”. The interface system might also randomly or systematically monitor or scan all or a portion of the available broadcasts for “special reports”. The interface system then monitors these channels for indicia of a “weather” information content broadcast. For example, the newscaster who appears to report the weather on a given show is usually the same, so that a pattern recognition system 2505 of the video frame could indicate the presence of that newscaster. In addition, the satellite photographs, weather radar, computer generated weather forecast screens, etc. are often similar for each broadcast. Finally, news segments, such as “weather” often appear at the same relative time in the broadcast. Using this information, the interface system selects certain broadcast segments for retention.

This retention begins at a beginning of a news segment, such as “weather”, stop recording during commercials, and continues after return from break, on all selected channels. In order to assist in making accurate decisions, the monitored broadcasts may be stored in a temporary storage medium until a decision is made, and thereafter transfer the recording to a more permanent storage medium if that be appropriate. It is noted that the system of the present invention is intelligent, and may therefore “learn” either explicitly, or through training by example. Therefore, if the system made an error during the process, the user may define the error of the system, e.g., a substitute newscaster or rearrangement of news segments, so that the interface system has a reduced likelihood of making the same error again. Thus, while such a system is inherently complex, it poses significant user advantages. Further, while the interface system itself is sophisticated, it provides simplicity, with inductive reasoning and deductive reasoning for the user.

Thus, a minimum of user interaction is required even for complex tasks, and nearly full automation is possible, as long as the user and apparatus are able to communicate to convey a preference. As a further embodiment according to the present invention, the interface system will stored transmitted data, and subsequently review that data, extracting pertinent information. The stored data may then be deleted from the storage medium. In this regard, the system may be self learning.

It is noted that various algorithms and formulae for pattern recognition, correlation, data compression, transforms, etc., are known to those skilled in the art, and are available in compendiums, such as Netravali, Arun N., and Haskell, Barry G., “Digital Pictures Representation and Compression”, Plenum Press, New York (1988); Baxes, Gregory A., “Digital Signal Processing, A Practical Primer”, Prentice-Hall, Englewood Cliffs, N.J. (1984); Gonzalez, Rafael C., “Digital Image Processing”, Addison-Wesley, Reading, Mass. (1987), and, of a more general nature, Press, William H. et al, “Numerical Recipes in C The Art of Scientific Computing”, Cambridge University Press, 1988.

EXAMPLE 12 Intelligent Adaptive VCR Interface

A further example of the use of the advanced intelligent features of the present invention is the use of the system to record, e.g., “live” musical performances. These occur on many “talk” shows, such as “Tonight Show” (NBC, 11:30 p.m. to 12:30 p.m., weeknights), “Saturday Night Live” (NBC 11:30 p.m. to 1:00 a.m. Saturday-Sunday), and other shows or “specials” such as the “Grammy Awards”. The interface, if requested by the user to record such performances, then seeks to determine their occurrence by, e.g., analyzing a broadcast schedule; interacting with the on-line database 2411; and by reference to the local database 2413. When the interface determines with high probability that a broadcast will occur, it then monitors the channel(s) at the indicated time(s), through the plurality of tuners 2502. The system may also autonomously scan broadcasts for unexpected occurrences.

In the case of pay-per-view systems and the like, which incorporate encrypted signals, an encryption/decryption unit 2509 is provided for decrypting the transmitted signal for analysis and viewing. This unit also preferably allows encryption of material in other modes of operation, although known decryption systems without this feature may also be employed with the present system. During the monitoring, the interface system acquires the audio and video information being broadcast, through the signal receiver 2408, and correlates this information with a known profile of a “live musical performance”, in the preference and event correlator 2412. This must be distinguished from music as a part of, e.g., a soundtrack, as well as “musicals” which are part of movies and recorded operas, if these are not desired by the user. Further, music videos may also be undesirable. When the correlation is high between the broadcast and a reference profile of a “live musical performance”, the system selects the broadcast for retention. In this case, the information in the intermediate storage 2503 is transferred to the plant 2507, which includes a permanent storage device 2508. The intermediate storage 2503 medium is used to record a “buffer” segment, so that none of the broadcast is lost while the system determines the nature of the broadcast. This, of course, allows an extended period for the determination of the type of broadcast, so that, while real-time recognition is preferred, it is not absolutely necessary in order to gain the advantages of the present invention. The buffer storage data, if not deleted, also allows a user to select a portion for retention that the interface system has rejected.

Thus, while it is preferable to make a determination in real time, or at least maintain real time throughput with a processing latency, it is possible to make an ex post facto determination of the nature of the broadcast program. By using an available delay, e.g., about 5 to about 300 seconds, or longer, the reliability of the determination can be greatly increased as compared to an analysis of a few frames of video data, e.g., about 15 to about 300 mS. An intermediate reliability will be obtained with a delay of between about 300 to about 5000 mS. As stated above, the storage system for this determination need not be uncompressed nor lossless, so long as features necessary to determine the character of the broadcast are present. However, it is preferred that for broadcast recording intended for later viewing, the storage be as accurate as possible, so that if a compression algorithm is implemented, it be as lossless as reasonable given the various constraints. The MPEG-2 standard would be applicable for this purpose, though other video compression systems are available.

In a preferred situation, approximately 5 minutes of broadcast material is analyzed in order to make a determination of the content. This broadcast material is stored in two media. First, it is stored in a format acceptable for viewing, such as video tape in a videotape recorder, or in digital video format, e.g., uncompressed, MPEG-2. Second, it is received in parallel by the computer control, where the data is subject to a number of recognition and characterization processes. These are performed in parallel and in series, to produce a stored extracted feature matrix. This matrix may contain any type of information related to the broadcast material, including an uncompressed signal, a compressed signal, a highly processed signal relating to information contained in particular frames and abstract features, spatially and temporally dissociated from the broadcast signal, yet including features included in the broadcast which relate to the content of the broadcast.

One possible method incorporates one or more digital signal processor based coprocessor elements, which may be present on, e.g., Nubus cards in the Macintosh Quadra 950, Apple Power PC, PCI card in Pentium-based MS-DOS/Windows 3.1, 3.11, 95, 98, NT computers (or Macintosh PCI-based computers), other Power PC based computers. These elements may be based on C-Cube CL550 (JPEG compression), Analog Devices ADSP-21020, Analog Devices ADSP-21060, AT&T (formerly American Telephone and Telegraph Co.) DSP32C, AT&T DSP3210, AMD 29000 series, Motorola DSP 96000ADS, Texas Instruments TMS 320C40, TMS 320C80, IBM Mwave, or other known devices. Other devices are also available from Analog Devices, AT&T, DSP Group, Motorola, NEC, SGS-Thomson, Sharp, Texas Instruments, Zilog, Zoran, and other vendors. See, EDN, May 11, 1995, pp. 40–106: Bursky, D., “Improved DSP ICs Eye New Horizons”, Electronic Design, Nov. 11, 1993, pp. 69–82. DSP systems, which generally have an architecture optimized for the efficient and rapid execution of repetitive numeric calculations, are desirable for certain pattern recognition tasks, and may be provided as a tightly coupled parallel processing array to increase throughput.

A known board containing a DSP is the MacDSP3210 by Spectral Innovations Inc., containing an AT&T digital signal processor and an MC68020 CISC processor, and which uses the Apple Real-time Operating System Executive (A/ROSE) and Visible Cache Operating System (VCOS). It is preferred that the processors employed be optimized for image processing, because of their higher throughput in the present image-processing applications, to process the video signals, and more other signal processors to analyze the audio signals. Of course, general purpose processors may be used to perform all calculations. An array processor which may be interfaced with a Macintosh is the Superserver-C available from Pacific Parallel Research Inc., incorporating parallel Inmos Transputers. Such an array processor may be suitable for parallel analysis of the image segment and classification of its attributes.

Pattern recognition processing, especially after preprocessing of the data signal by digital signal processors and image compression engines, may also be assisted by logical inference engines, such as FUTURE (Fuzzy Information Processing Turbo Engine) by The Laboratory for International Fuzzy Engineering (LIFE), which incorporates multiple Fuzzy Set Processors (FSP), which are single-instruction, multiple data path (SIMD) processors. Using a fuzzy logic paradigm, the processing system may provide a best fit output to a set of inputs more efficiently than standard computational techniques, and since the presently desired result requires a “best guess”, rather than a very accurate determination, the present interface is an appropriate application of this technology.

As noted above, these processors may also serve other functions such as voice recognition for the interface, or extracting text from video transmissions and interpreting it. It is also noted that, while some of these coprocessing engines are now costly, these costs are decreasing and the present invention therefore includes the use of sophisticated present designs as well as future devices which may be used to perform the stated functions. The continued development of optical computers may also dramatically reduce the cost of implementing this aspect of the present invention; however, the present state of the art allows the basic functions to be performed. See attached appendix of references, incorporated herein by reference, detailing various optical computing designs.

A real time operating system may be employed, of which there are a number of available examples. Some older examples include SPOX DSP operating system, IBM's Mwave operating system and AT&T's VCOS operating system. These operating systems, and possibly others, are to be supported by Microsoft Inc.'s Windows 95 operating system Resource Manager function.

It is noted that various methods are available for determining a relatedness of two sets of data, such as an image or a representation of an image. These include the determination of Hausdorff distance, fuzzy correlation, arithmetic correlation, mean square error, neural network “energy” minimization, covariance, cross correlation, and other known methods, which may be applied to the raw data or after a transformation process, such as an Affine transformation, a Fourier transformation, a Gabor transformation, a warping transformation, a color map transformation, and the like. Further, it is emphasized that, in image or pattern recognition systems, there is no need that the entire image be correlated or even analyzed, nor that any correlation be based on the entirety of that image analyzed. Further, it is advantageous to allow redundancy, so that it is not necessary to have unique designations for the various aspects of the data to be recognized, nor the patterns to be identified as matching the uncharacterized input data.

The MSHELL from Applied Coherent Technology is a software system that runs on a Mercury MC3200 array processor, in conjunction with a Data Translation DT2861 or DT2862. The NDS1000 Development System from Nestor, Inc., provides image recognition software which runs on a PC compatible computer and a Data Translation DT2878.

The C-Cube CL550 is disclosed in “C-Cube CL550 JPEG Image Compression Processor”, Preliminary Data Book, August 1991, and addendum dated Nov. 20, 1991, and products incorporating the CL550 include the JPEG Video Development Kit (ISA bus card with Chips and Technologies PC video 82C9001A Video Window Controller), and the C-Cube CL550 Development Board/PC for ISA Bus (CL550, for use with Truevision TARGA-16 or ATVista cards) or for NuBus (Macintosh). The so-called C-Cube “CL950” is a MPEG decoder device. Such a device as the CL950 may be particularly useful for use in the present VCR for reproducing compressed program material, which may be compressed by the present apparatus, or may be used for decompressing pre-compressed program material. Other MPEG-1 and MPEG-2 encoding and decoding devices are known.

It is noted that all functions of a VCR would also be facilitated by the use of such powerful processors, and thus it is not only these advanced functions which are enabled by these advanced processors and coprocessors. It is also noted that these image recognition functions need not necessarily all be executed local to the user, and may in fact be centralized with resultant processed data transmitted to the remote user. This would be advantageous for two reasons: first, the user need not have an entire system of hardware localized in the VCR, and second, many of the operations which must be performed are common to a number of users, so that there is a net efficiency to be gained.

EXAMPLE 13 Intelligent Adaptive VCR Interface

The interface of the present invention incorporates an intelligent user interface level determination. This function analyzes the quality of the user input, rather than its content. Thus, this differs from the normal interface user level determination which requires an explicit entry of the desired user level, which is maintained throughout the interface until explicitly changed. The present interface may incorporate the “smart screen” feature discussed above, which may, through its analysis of the past user interaction with the interface predict the most likely predicted user input function. Thus, the predictive aspects of the present invention may be considered a related concept to the intelligent user level interface of the present invention. However, the following better serves to define this aspect of the invention.

The input device, in addition to defining a desired command, also provides certain information about the user which has heretofore been generally ignored or intentionally removed. With respect to a two-dimensional input device, such as a mouse, trackball, joystick, etc., this information includes a velocity component, an efficiency of input, an accuracy of input, an interruption of input, and a high frequency component of input. This system is shown schematically in FIG. 21, which has a speed detector 2104, a path optimization detector 2105, a selection quality detector 2106, a current programming status 2108, an error counter 2109, a cancel counter 2110, a high frequency signal component detector 2112, an accuracy detector 2113 and a physio-dynamic optimization detector 2114. In addition, FIG. 21 also shows that the interface also uses a past user history 2107, an explicit user level choice 2111 and an explicit help request 2115.

This list is not exclusive, and is somewhat dependent on the characteristics of the specific input device. For a mouse, trackball, or other like device, the velocity or speed component refers to the speed of movement of the sensing element, i.e. the rotating ball. This may also be direction sensitive, i.e., velocity vector. It is inferred that, all other things being equal, the higher the velocity, the more likely that the user “knows” what he is doing.

The efficiency of input refers to two aspects of the user interface. First, it refers to the selection of that choice which most simply leads to the selection of the desired selection. For example, if “noon” is an available choice along with direct entry of numbers, then the selection of “noon” instead of “12:00 p.m.” would be more efficient. The second aspect of efficiency has to do with the path taken by the user in moving a graphic user interface cursor or input device from a current position to a desired position. For example, a random curve or swiggle between locations is less efficient than a straight line. This effect is limited, and must be analyzed in conjunction with the amount of time it takes to move from one location of a cursor on the screen to another; if the speed of movement is very rapid, i.e. less than about 400 mS for a full screen length movement, or less than about 300 mS for small movements, then an inefficiency in path is likely due to the momentum of the mouse and hand, momentum of the rolling ball, or a physiological arc of a joint. This aspect is detected by the physio-dynamic optimization detector 2114. Thus, only if the movement is slow, deliberate, and inefficient, should this factor weigh heavily. It is noted that arcs of movement, as well as uncritical damping of movement around the terminal position may be more efficient, and a straight path actually inefficient, so that the interface may therefore calculate efficiency based on a complex determination, and act accordingly where indicated.

Thus, an “efficient” movement would indicate an user who may work at a high level, and conversely, an inefficient movement would indicate a user who should be presented with simpler choices. The efficiency of movement is distinguished from gestures and path dependent inputs, such as drawing and painting. These may be distinguished based on machine status or context. Further, the interface may recognize gestures in may contexts. Therefore, gesticulations must be distinguished from command inputs before further processing. Gesticulations, like path efficiency, may also be analyzed separately from the basic command input, and therefore may be provided as a separate input stream on an interface level rather than an application level, thus allowing cross application operation.

Likewise, if a movement is abrupt or interrupted, yet follows an efficient path, this would indicate a probable need for a lower user interface level. This would be detected in a number of elements shown in FIG. 21, the speed detector 2104, a high frequency signal component detector 2112, an accuracy detector 2113 and a physio-dynamic optimization detector 2114. In addition, FIG. 21 also shows the use of a past user history 2107, an explicit user level choice 2111 and an explicit help request 2115.

While the interface may incorporate screen buttons which are smart, i.e. those which intelligently resolve ambiguous end locations, the accuracy of the endpoint is another factor in determining the probable level of the user. Thus, for example, if a 14″ color monitor screen is used, having a resolution of 640 by 480 pixels, an accurate endpoint location would be within a central area of a screen button of size about 0.3″ by about 1.0″, would be an area of about 0.25″ by about 0.75″. A cursor location outside this location, but inside the screen button confines would indicate an average user, while a cursor location outside the screen button may be inferred to indicate the button, with an indication that the user is less experienced in using the pointing device.

Finally, in addition to the efficiency of the path of the cursor pointing device, a high frequency component may be extracted from the pointer signal by the high frequency signal component detector 2112, which would indicate a physical infirmity of the user (tremor), a distraction in using the interface, indecision in use, or environmental disturbance such as vibration. In this case, the presence of a large amount of high frequency signal indicates that, at least, the cursor movement is likely to be inaccurate, and possibly that the user desires a lower user level. While this is ambiguous based on the high frequency signal content alone, in conjunction with the other indicia, it may be interpreted. If, for example, the jitter is due to environmental vibrations, and the user is actually a high level user, then the response of the user level adjust system would be to provide a screen display with a lowered required accuracy of cursor placement, without necessarily qualitatively reducing the implied user level of the presented choices, thus, it would have an impact on the display simplification 2103, with only the necessary changes in the current user level 2101.

Alternatively, the user may input a gesture, i.e., a stylized input having no other command input meaning, which may be detected by analyzing the input. The input may be a manual input, voice, image or the like. A number of different gestures may be recognized. These gestures are generally explicit inputs, which allow a voluntary action to be interpreted as input information to the interface.

EXAMPLE 14 Intelligent Telephone Device Interface

Likewise, the present interface could be used to control complex telecommunications functions of advanced telephone and telecommunications equipment. In such a case, the user display interface would be a video display, or a flat panel display, such as an LCD display. The interface would hierarchically present the available choices to the user, based on a probability of selection by the user. The input device would be, for example, a small track ball near the keypad. Thus, simple telephone dialing would not be substantially impeded, while complex functions, such as call diversion, automated teledictation control, complex conferencing, caller identification-database interaction, and videotel systems, could easily be performed.

EXAMPLE 16 Character Recognition of Video

The present invention may incorporate character recognition from the video broadcast for automatic entry of this information. This is shown schematically in FIG. 24, with the inclusion of the videotext and character recognition module 2414. This information is shown to be transmitted to the event characterization unit 2407, where the detected information is correlated with the other available information. This information may also be returned to the control 2402. Examples of the types of information which would be recognized are titles of shows, cast and crew from programming material, broadcast special alerts, time (from digital display on special access channels), stock prices from “ticker tape” on special access channels, etc. Thus, this technology adds functionality to the interface. In addition, subtitled presentations could be recognized and presented through a voice synthesizer, to avoid the necessity of reading the subtitle. Further, foreign language subtitles could be translated into, e.g., English, and presented. In a particular embodiment, certain game shows, such as “Wheel of Fortune” have alphanumeric data presented as a part of the programming. This alphanumeric text may be extracted from the image.

In a preferred embodiment, the character recognition is performed in known manner on a buffer memory containing a frame of video, from a device such as a Data Translation DT2851, DT2853, DT2855, DT2867, DT2861, DT2862 and DT2871. A contrast algorithm, run on, for example, a Data Translation DT2858, DT2868, or DT2878, first removes the background, leaving the characters. This works especially well where the characters are of a single color, e.g. white, so that all other colors are masked. After the “layer” containing the information to be recognized is masked, an algorithm similar to that used for optical character recognition (OCR) is employed. See, U.S. Pat. No. 5,262,860, incorporated herein by reference. These methods are well known in the art. This may be specially tuned to the resolution of the video device, e.g. NTSC, Super Video Home System (S-VHS), High Definition Television and/or Advannced Television System Committee (HDTV/ATSC-various included formats), Improved definition television (IDTV), Enhanced Definition Television (EDTV), Multiple Sideband Encoding (MUSE), Phase Alternate Line (PAL), Sequential Coleur à Memoire (SECAM), MPEG-2 digital video, or other analog or digital transmission and/or storage formats, etc. In addition, since the text normally lasts for a period in excess of one frame, a spatial-temporal image enhancement algorithm may be employed to improve the quality of the information to be recognized, if it is indistinct in a single frame.

EXAMPLE 17 Smart House Interface

The present invention may also be incorporated into other types of programmable controls, for example those necessary or otherwise used in the control of a smart house. See, “The Smart House: Human Factors in Home Automation”, Human Factors in Practice, December 1990, 1–36. The user interface in such a system is very important, because it must present the relevant data to the user for programming the control to perform the desired function. A smart house would likely have many rarely used functions, so that both the data and the available program options must be presented in the simplest manner consistent with the goal of allowing the user to make the desired program choice. For example, a smart house system with appropriate sensors might be used to execute the program: “start dishwasher, if more than half full, at 9:00 p.m.” This program might also include a program to load soap into the dishwasher or to check if soap is already loaded. A user who wishes to delay starting until 11:00 p.m. would be initially presented with the defaults, including start time as an option, which would be simply modified by correcting the starting time. The next time the same user wishes to program the device, an algorithm might change the predicted starting time to, e.g. 10:00 p.m., which is a compromise between the historical choices. Alternatively, the new predicted start time might be 11:00 p.m., the last actually programmed sequence. Finally, the next predicted start time might remain at 9:00 p.m. The resolution of these choices would depend on a number of factors: a preprogrammed expert system; any other prior history of the user, even with respect to other appliances or in other situations; the context, meaning any other contemporaneously programmed sequences; and an explicit input from the user as to how the inputs should be evaluated for predictive purposes.

The expert system would balance factors, including disturbing noise from the dishwasher, which might be objectionable while persons are near the dishwasher, people are sleeping, or during formal entertainment. On the other hand, if the dishwasher is full, or its cleaned contents are needed, the dishwasher should run. Some persons prefer to reshelve dishes in the evening, before sleep, so in those cases, the dishwasher should complete its cycle before bedtime. The dishwasher, on a hot water cycle, should not run during showers or baths, and preferably should not compete with a clothes washer for hot water. The dishwasher preferably does not run during peak electrical demand times, especially if electrical rates are higher. Water conserving cycles should be selected, especially during droughts or water emergencies. If dishes remain in the dishwasher for an extended period, e.g., overnight, a moistening cycle may be employed to help loosen dirt and to help prevent drying. Thus, the expert system is preprogrammed for a number of high level considerations that might be common to a large number of users of the system, thus shortening the required training time of the system to learn the preferences of the user. Such a sophisticated system may eliminate the need entirely for adaptive responses, based on weighing of considerations provided by the user. Of course, other considerations may also be included for the operation or delay of operation of the dishwasher. Further, these considerations are exemplary of the types of considerations which might be employed in an expert system in a smart house.

The prior history of the user provides an excellent source of information regarding the preferences of the user, although this is sometimes not the most efficient means, and may often include contradictory data. This historical use data is therefore analyzed in a broad context in order to extract trends, which over a number of uses may be further extracted as “rules”. Often, the user history data will be applied at a high level, and will interact with preexisting rules of the expert system, rather than to create new rules. In this case, the expert system preferably includes a large number of “extra rules”, i.e., those with an a priori low probability or low weighing, providing a template for future pattern matching. The past history may be evaluated in a number of ways. First, an expert system may be used to analyze the past usage pattern. Second, a neural network may be trained using the historical data along with any corrective feedback. Third, the historical data may be used to alter fuzzy logic rules or classifications, either by expert system, neural network, or by other known means.

The context of use may also be used to determine a desired or predicted action. Therefore, if on a single occasion, a number of changes are made, for example during a large house party, the standard predictions would not be altered, and thus a normal program would remain in effect. Of course, a new “house party” sequence would then be recognized and included as a new type of sequence for future evaluation. For example, a house party sequence might encompass a number of house systems. Thus, the delay of dishwasher until 11:00 p.m. allows all dishes from the party to be placed in the dishwasher before starting. An alarm system would be generally deactivated, although various zones may be provided with different protection; e.g., a master suite may be off-limits, with an alarm transmitting a signal to a user's beeper, rather than a call to police or alarm service company. During the summer, the air conditioner might run even if doors and windows are open, even if the normal program prompts for door closings before the air conditioner is turned on. Likewise, exterior lighting would be turned on at dusk, with bug lights turned on during the entire party. The user might individually make such decisions, which would be recognized as a group due to their proximity in time, or delineate the actions as a group. Thereafter, where some of these choices are made, and the profile of choices matches a “party” style, the remainder of the choices may be presented as a most likely or predicted choice. The group of choices together might also be selected from a menu of choices.

Context also relates to sensor data, which might include sensors in particular appliances or unrelated sensors. For example, infrared motion detectors may be used to estimate the number of persons present in a house. Likewise, heavy use of a bathroom, as detected by flushes, frequent light transitions or door openings, might also be useful as data to estimate a crowd size. Temperature sensors, video imaging sensors, perimeter sensors, electrical sensors relating to the status of appliances and machinery, and other types of sensors may provide data for context determination.

Of course, explicit inputs must also be accommodated, which may be atomic instructions or complex combinations of instructions which may control a single house system or a number of house systems simultaneously. The explicit input preferably comes by way of the adaptive interface described throughout the present application, or an interface incorporating particular aspects thereof.

The smart house system also controls the climate control system. Thus, it could coordinate temperatures, air flow and other factors, based on learned complex behaviors, such as individual movement within the dwelling. Since the goal of the programming of the smart house is not based on the storage of discrete information, but rather the execution of control sequences at various times and under certain circumstances, the control would differ in various ways from that of a VCR. However, the user interface system, adaptive user level, help system, and the like would be common to both types of system. This differs from the Fuzzy Logic controlled air conditioner available (in Japan) from Mitsubishi in that these prior art devices do not have an intelligent interface of the present invention. It should also be noted that the control for the VCR could be the same control as that for the smart house, so that the common elements are not redundant. Therefore, by applying a single control to many tasks, a common user interface is used, and the cost is reduced.

EXAMPLE 18 Programmable Environmental Controller

The present Example relates to a programmable environmental controller application. In this case, a sensor or sensor array is arranged to detect a change in the environment which is related to a climatic condition, such as an open door. On the occurrence of the door opening, the system would apply a pattern recognition analysis to recognize this particular sensor pattern, i.e. a mass of air at a different temperature entering the environment from a single location, or a loss of climate controlled air to a single location. These sensor patterns must be distinguished from other events, such as the action of appliances, movement of individuals in the vicinity of the sensor, a shower and other such events. It is noted that in this instance, a neural network based adaptive controller may be more efficient than a standard fuzzy logic system, because the installation and design of such a system is custom, and therefore it would be difficult to program fuzzy set associations a priori. In this case, a learning system, such as a neural network, may be more efficient in operation and produce a better result than other adaptive methods. The training procedure may be fully automated, (with manual feedback provided where necessary to adjust the control parameters) so long as sufficient sensors are provided for controlling the system, and also that an initial presumption of the control strategy is workable during the training period. In the case of an HVAC system, the initial strategy incorporated is the prior art “bang-bang” controller, which operates as a simple thermostat, or multi-zone thermostat. As a better starting point, a fuzzy logic temperature controller may be modeled and employed. Other known strategies which are not often used in environmental control include the proportional-integral-differential controller (PID).

It is noted that the HVAC system may also be of a type which is inoperable with standard type controllers; for example, the system may be such as to produce temperature oscillations, or significant temperature or pressure gradients. In this case, the default control system must be provided to compensate the system, allowing more subtle corrections and adjustments to be made based on preferences. Thus, an expert system is provided, which is updated based on user input, and which receives context information, including sensor data and other inputs. Explicit user preferences and programming are also input, preferably with an interface in accordance with the present invention or incorporating aspects thereof.

In this example, which may be described with reference to FIG. 23, sufficient sensors in a sensor array 2301 are provided, being light, temperature, humidity, pressure, air flow and possibly a sensor for determining an event proximate to the sensor, such as door opening. While a single sensor array 2301 provides input to the present control, a plurality of sensor arrays are preferably employed in complex installations, such as that described here. The sensors, with the possible exceptions of the flow sensor and event sensor, are housed in a single sensor head. Further, the temperature and pressure sensors may be combined in a single integrated circuit by known means. The light and temperature sensors are known to those skilled in the art, and need not be described herein. The pressure sensor may be a Sensym strain gage pressure transducer, a Motorola pressure transducer device, or the like, which are known in the art. Alternatively, other types of sensors may be used, for example a micromachined silicon force balance pressure transducer, similar in electrical design to the Analog Devices monolithic accelerometers, ADXL-50 or ADXL-05.

The humidity sensor is preferably an electronic type, producing an electrical signal output. It need not be internally compensated for the other measured environmental factors, as the constellation of sensors may compensate each other. The air flow sensor may be based on pressure differentials, using the electronic pressure sensor described above, or may be a mechanical vane type, which is based on flows. In most applications, a single flow axis will be sufficient, however, in some circumstances, a two or greater axis sensor will be required. Further, in the case of large volume areas, complex turbulent flow patterns may be relevant, for which known sensors exist. Laser based air flow sensors may be employed, if desired. LIDAR sensors may be used to determine flow rate, direction, and turbulence.

The event sensor may be of any type, and depends particularly on the event being measured. In the present case, where a door opening is to be detected, it is preferred that the environmental control be interfaced with a perimeter intrusion alarm system, which, for example, provides a magnet embedded in the door and a magnetic reed switch in the door frame. Individual sensors are normally wired to the alarm control panel, thus providing central access to many or all of the desired event detection sensors while minimizing the added cost. The event detector may also be an ultrasonic, infrared, microwave-Doppler, mechanical, or other type of sensor. Wireless sensors may also be used, communicating via infrared beams, acoustic, radio frequency, e.g., 46–49 MHz, 900 MHz, or other bands, using analog, digital or multilevel quantized digital AM, FM, PSK, QAM, or other modulation scheme, or a combination thereof. Spread spectrum devices may be employed, as well as time, code or frequency multiplexing or a combination thereof. Various failsafe mechanisms are preferably included, including those identifying transmitter or receiver failure, communication interference or message collision, and other conditions. A reverse communication channel may also be included, either symmetric in band, or asymmetric in band or out of band, for communication with the sensor or apparatus associated with the sensor, and as part of the failsafe system. A forward error correction protocol is preferably effected, which may detect errors and include error correcting codes for digital transmissions. Digital data may be encrypted, and the transmission modulation scheme may also include an encrypted sequence of frequency, phase, convolution, noise, or other modulation parameter.

While wireless data transmission as described above may be used, the preferred method of receiving sensor information is through a serial digital or analog (i.e., 4–20 mA transmitter) data transmission which may be multiplexed and/or part of a local area network scheme, with minimal local processing of the sensor data by the microprocessor 2302 with the serial link 2302 a in the sensor head. Such serial digital protocols and physical transport layers include Echelon LON-works, BSR X-10, CEBUS, RS-232, RS-423, Apple ADB, Appletalk, Ethernet (10 base T, 10 Base 2, 10 base 5, 100 Base T, 100 base VG), ATM, USB, IEEE-1394, Homerun (Intel/Tut), etc. This system allows the central control 2303 to incorporate the desired processing, e.g., by the pattern recognition system 2304, etc., while minimizing the installation expense. A simple microprocessor device 2302 in the sensor head interfaces the sensing elements, and may provide analog-to-digital conversion, or other conversion which may be necessary, of the sensor signal. In the case of a serial digital data transmission, the local microprocessor formats the sensor data, including a code indicating the sensor serial number and type, the sensor status (i.e., operative, defective, in need of maintenance or calibration, etc.), the sensor data, and an error correcting code. In the case that the data is transmitted on a local area network, the microprocessor also arbitrates for bus usage and the messaging protocol.

The control, it must be understood, has a number of available operative systems at its disposal, comprising the plant 2306. In this case, the system is a forced air heating and cooling system. This system has a heating unit, a humidifier, blowers, a cooling unit (which also dehumidifies), ducts, dampers, and possible control over various elements, such as automated door openers.

As described above, the system is installed with a complete array of sensors, some of which may be shared with, or a part of, other control systems in the environment, and begins operation with a basic acceptable initial control protocol. The system then receives data from the sensors, and correlates data from the various sensors, including the event sensors, with the operation of the systems being controlled. In such a case, a “door open” event may be correlated with a change in other measured variables. The system then correlates the control status with the effect on the interrelation of the measured variables. Thus, the system would detect that if the blower is operating while the door is open, then there is a high correlation that air will flow out of the door, unless a blower operates to recirculate air from a return near the door. Thus, the system will larn to operate the proximate return device while the door is open and the blower is on. Once this correlation is defined, the system may further interrelate the variables, such as a wind speed and direction outside the door, effects of other events such as other open doors, the absolute and relative speeds of the blowers and the return device, the effect of various damper devices, etc. It is further noted that, under some circumstances, an exchange of air through an open door is desired, and in such instance, the system may operate to facilitate the flow through such an open door. Finally, the system must be able to “learn” that conditions may exist which produce similar sensor patterns which should be handled differently. An example is a broken, defective or inoperative sensor. In such a case, the system must be able to distinguish the type of condition, and not execute an aggressive control algorithm in an attempt to compensate for an erroneous reading or otherwise normal event. This requires the intelligent control of the present invention. In order to distinguish various events, sensors which provide overlapping or redundant information, as well as providing a full contextual overview, should be provided as a part of the system.

It is further noted that energy efficiency is a critical issue in climate control systems, and an absolute and continuous control over the internal environment may be very inefficient. Thus, the starting of large electrical motors may cause a large power draw, and simultaneous starting of such equipment may increase the peak power draw of a facility, causing a possible increase in the utility rates. Further, some facilities may operate on emergency or private power generation (co-generation) which may have different characteristics and efficiency criteria. These factors may all be considered in the intelligent control. It is also noted that a higher efficiency may also be achieved, in certain circumstances, by employing auxiliary elements of the climate control system which have a lower capacity and lower operating costs than the main elements. Thus, for example, if one side of a building is heated by the sun, it may be more efficient to employ an auxiliary device which suitably affects, i.e. compensates, only a part of the building. If such equipment is installed, the aggregate efficiency of the system may be improved, even if the individual efficiency of an element is lower. Likewise, it may be preferable to run a 2 ton air conditioning unit continuously, rather than a 5 ton air conditioning unit intermittently. The present intelligent control allows a fine degree of control, making use of all available control elements, in an adaptive and intelligent manner.

Returning to the situation of a door opening event, the system would take appropriate action, including: interruption of normal climate control until after the disturbance has subsided and normal conditions are achieved; based on the actual climatic conditions or predicted climatic conditions begin a climate compensation control, designed to maximize efficiency and also maintain climatic conditions during the disturbance, as well as return to normal after the disturbance; optionally, during the door opening disturbance, the system would control a pressure or flow of air to counterbalance a flow through the door, by using a fan, blower or other device, or halting such a device, if necessary. It is also noted that the climatic control system could also be outfitted with actuators for opening and closing doors and windows, or an interface with such other system, so that it could take direct action to correct the disturbance, e.g., by closing the door. The climate between the internal and external ambients may differ in temperature, humidity, pollutants, or the like, and appropriate sensors may be employed.

It is thus realized that the concepts of using all available resources to control an event, as well as using a predictive algorithm in order to determine a best course of action and a desired correction are a part of the present invention.

EXAMPLE 19 Remote Control Hardware

A remote control of the present invention may be constructed from, for example, a Micromint (Vernon, Conn.) RTC-LCD, RTC-V25 or RTC-HC11 or RTC180 or RTC31/52, and RTC-SIR, in conjunction with an infrared transmitter and receiver, input keys and a compatible trackball, which may provide raw encoder signals, or may employ a serial encoder and have a serial interface to the processor module. A power supply, such as a battery, is used. The use, interfacing and programming of such devices is known to those skilled in the art, and such information is generally available from the manufacturer of the boards and the individual circuit elements of the boards. The function of such a remote control is to receive inputs from the trackball and keys and to transmit an infrared signal to the controller.

The processor and display, if present, may provide added functionality by providing a local screen, which would be useful for programming feedback and remote control status, as well as compressing the data stream from the trackball into a more efficient form. In this case, certain of the extracted information may be relevant to the determination of the user level, so that information related to the user level would be analyzed and transmitted separately to the controller by the infrared transmitter. If the local LCD screen is used in the programming process, then the main controller would transmit relevant information to the remote display, by a reverse-channel infrared link. These components are known in the art, and many other types may also be used in known manner.

In known manner, available personal digital assistants (“PDAs”), available from 3Com (Palm Pilot III), Microsoft Windows CE-based devices, Apple (“Newton” model 100, 110, 120), Tandy, Poquet, Sharp, Casio, AT&T (Eo 440), Hewlett-Packard, etc. may also be employed as a human interface device.

EXAMPLE 20 Medical Device Interface

The interface and intelligent control of the present invention are applicable to control applications in medicine or surgery. This system may also be described with reference to the generic system drawings of FIGS. 23 and 24. In this case, an operator identifies himself and enters information regarding the patient, through the interface 2305. The interface 2305 automatically loads the profile 2406 of both the operator and the patient, if the device is used for more than one at a time, and is connected to a database containing such information, such as a hospital central records bureau. The interface may be connected to various sensors, of the input device 2401, such as ambient conditions (temperature, humidity, etc.), as well as data from the patient, such as electrocardiogram (EKG or ECG), electromyograph (EMG), electroencephalogram (EEG), Evoked Potentials, respirator, anesthesia, temperature, catheter status, arterial blood gas monitor, transcutaneous blood gas monitor, urinary output, intravenous (IV), intraperitoneal (IP), Intramuscular (IM), subcutaneous (SC), intragastric or other types of solutions, pharmaceutical and chemotherapy administration data, mental status, movement, pacemaker, etc. as well as sensors and data sources separate from the patient such as lab results, radiology and medical scanner data, radiotherapy data and renal status, etc. Based on the available information, the interface 2405, using the simple input device and the display screen described above, presents the most important information to the operator, along with a most probable course of action. The user then may either review more parameters, investigate further treatment options, input new data, or accept the presented option(s). The system described has a large memory in the signal analysisng medical devices and for applying artificial intelligence to assist in diagnosis, the present system allows for individualization based on both the service provider and the patient. Further, the present invention provides the improved interface for interaction with the system.

It is further noted that, analogously to the library function discussed above, medical events may be characterized in the characterization unit 2407 and recorded by the plant 2404, so that a recording of the data need not be reviewed in its entirety in order to locate a particular significant event, and the nature of this event need not be determined in advance. It is also noted that the compression feature of the recorder of the present invention could be advantageously employed with the large volume of medical data that is often generated. Medical data image data may be compressed as known in the art, by standard image compression techniques, and/or image compression techniques optimized for radiology, nuclear medicine and ultrasonography data. Other types of data may be compressed using lossless algorithms, or by various vector quantization, linear excited models, or fractal compression methods. It is finally noted that, because of its ability to store and correlate various types of medical data in the characterization unit 2407, the system could be used by the operator to create notes and discharge summaries for patients, using the database stored in the local database 2413, as well as the user history and preferences 2406. Thus, in addition to saving time and effort during the use of the device, it would also perform an additional function, that of synthesizing the data, based on medical significance.

In addition to providing the aforementioned intelligence and ease of use, the present example also comprises a control 2402, and may interface with any of the sensors and devices, performing standard control and alarm functions. However, because the present control 2402 is intelligent and has pattern recognition capability, in addition to full data integration from all available data sources, it may execute advanced control functions. For example, if the present control 2402 is interfaced to a controlled infusion pump for, e.g., morphine solution, in e.g., a terminally ill patient, then certain parameters must be maintained, while others may be flexible. For example, a maximum flow rate is established as a matter of practice as a safety measure; too high a flow rate could result in patient death. However, a patient may not need a continuous infusion of a constant dose of narcotic. Further, as the patient's status changes, the level of infusion may be advantageously altered. In particular, if the renal status of the patient were to change, the excretion of the drug may be impaired. Therefore, by providing the controller with a urinary output monitor, it could immediately suppress the morphine infusion as soon as the renal output is recognized as being decreased, and further indicate an alarm condition. Further, it may be advantageous to provide a diurnal variation in the infusion rate, to provide a “sleep” period and a period of heightened consciousness with correspondingly lower levels of narcosis. Where various tests, procedures or interviews are scheduled, an appropriate level of narcosis and/or analgesia may also be anticipatorily provided at an appropriate time.

As another example of the use of the present device as a medical controller, the control 2402 could be interfaced with a cardiac catheter monitor, as a part of the signal receiver 2408. In such a case, normally, alarms are set based on outer ranges of each sensor measurement, and possibly a simple formula relating two sensor measurements, to provide a useful clinical index. However, by incorporating the advanced interface and pattern recognition function of the present invention, as well as its ability to interface with a variety of unrelated sensors, the present device, including the present control, may be more easily programmed to execute control and alarm functions, may provide a centralized source of patient information, including storage and retrieval, if diverse sources of such information are linked, and may execute advanced, adaptive control functions. The present control 2402 is equipped to recognize trends in the sensor data from the signal receiver 2408, which would allow earlier recognition and correction of various abnormal conditions, as well as recognizing improvements in conditions, which could allow a reduction in the treatment necessary. Further, by allowing a fine degree of control, parameters may be maintained within optimal limits for a greater percentage of the time. In addition, by monitoring various sensors, various false alarms may be avoided or reduced. In particular, false alarms may occur in prior art devices even when sensors do not indicate a dangerous condition, merely as a safety precaution when a particular parameter is out of a specified range. In such a case, if a cause of such abnormal condition may be identified, such as patient movement or the normal activities of the patient's caretakers, then such condition may be safely ignored, without indicating an alarm. Further, even if a sensor parameter does in and of itself indicate a dangerous condition, if a cause, other than a health risk, may be identified, then the alarm may be ignored, or at least signaled with a different level of priority. By providing an intelligent and active filter for false alarm events, the system may be designed to have a higher level of sensitivity and specificity to real health risks, and further to provide a finer level of control based on the sensor readings, with fewer false positive readings.

EXAMPLE 21 Securities Trading Terminal Interface

The present invention is also of use in automated securities, debt, variable yield and currency trading systems, where many complex functions are available, yet often a particular user under particular circumstances will use a small subset of the functionality available at a given time. Such a situation would benefit from the present interface, which provides adaptive user levels, prioritized screen information presentation, and pattern recognition and intelligent control. A securities trading system is disclosed in U.S. Pat. No. 5,034,916, for a mouse driven Fast Contact Conversational Video System, incorporated herein by reference. The present system relates primarily to the user terminal, wherein the user must rapidly respond to external events, in order to be successful. In such a case, the advantages of the application of an interface according to the present invention are obvious, and need not be detailed herein. However, the pattern recognition functions of the present invention may be applied to correspond to the desired actions of the trader, unlike in prior intelligent trading systems, where the terminal is not individually and adaptively responsive to the particular user. Thus, the system exploits the particular strengths of the user, facilitating his actions, including: providing the desired background information and trading histories, in the sequence most preferred by the user; following the various securities to determine when a user would execute a particular transaction, and notifying the user that such a condition exists; monitoring the success of the user's strategy, and providing suggestions for optimization to achieve greater gains, lower risk, or other parameters which may be defined by the user. Such a system, rather than attempting to provide a “level playing field” to all users of like terminals, allows a user to use his own strategy, providing intelligent assistance. By enhancing the interface, a user becomes more productive with fewer errors and fastr training.

EXAMPLE 22 Fractal Theory Pattern Recognition

Affine transforms are mathematical manipulations of data in two dimensions, wherein the manipulation comprises a rotation, scaling and a displacement for each of the two coordinates. Schroeder, M., Fractals, Chaos, Power Laws, W.H. Freeman & Co., New York (1991). Of course, Affine transforms of higher dimensionality may also be employed. In describing an image using Affine transforms, the degree of matching between an image and the mathematical description of that image may be related by a number of iterations, and the fewer the iterations, the less data used to describe the image. Of particular importance in the field of graphics is the speed of “convergence”, i.e., that a relatively few iterations are necessary in order to describe an image with sufficient precision to be visually useful. Therefore, the Affine transform mathematical specifications may be far more compact than the raw image data, and these specifications compare favorably to other types of image compression, such discrete cosine transformation (DCT) compression schemes, including JPEG, depending on a number of factors.

Because the Affine transform may be used to produce a compact visual description of an image, among other reasons, the present invention applies this transform to a pattern matching system for analyzing image contents.

Pattern recognition, in this case, may proceed on an image basis, to match similar images, or on an object basis, in which portions of images are matched. It is preferred that the pattern matching system be robust, i.e., tolerant of various alterations of an image, artifacts, interference and configurational changes, while specific enough to allow object differentiation.

In the case of video images, therefore, it is preferred that various two-dimensional projections of three-dimensional objects, in various “poses”, be classified the same. This therefore requires that, in analyzing a two-dimensional image, the object be extracted from a background image and separated from other objects. Further, degrees of freedom may be determined, such as through analysis of a sequence of frames to reveal relative motion or change of portions of the object with respect to other portions. Finally, the object in the image must be compared to three dimensional models, through various projections.

In the case of two dimensional image analysis, the image should be analyzed according to1t0b0s10.00 a robust starting criteria, so that the similarity of images may be determined by comparison of normalized Affine transformation coefficients.

Fractal analysis, the study of self-similarity, and a superset of Affine transformation, allows a compact representation of an image or an object in an image, and due to its encompassing of various spatial relationships of object parts, allows normalized transforms to be compared. In other words, assuming that the object is extracted from a background scene, and various degrees of freedom are identified, an Affine transformation may be applied, which will yield a similar result for an image of the same object in a different “pose”, i.e., with different exercise of its degrees of freedom. While in general, Affine transformations are described with respect to two-dimensional images, these may also be applied to three dimensional images. Thus, if a triangular polygon is rotated, scaled and displaced in a two dimensional image, a tetrahedron is rotated, scaled and displaced in a three dimensional system. Further, analogies may also be drawn to the time dimension (although geometric forms which are rotated, scaled and displaced over time are not given trivial names). Because, in a contractive Affine transformation (one in which the scaling factor of successive iterations is less than 1), continued iterations are less significant, objects described with varying level of detail may be compared. Even images which are not normalized may still be compared, because at every level of the transform, slight changes in rotation, scale and displacement are accounted for.

According to the present invention, nonlinear self-similarity may also be used. Further, in objects having more than two dimensions, linear scaling other than rotation, scaling and displacement may be described.

It is noted that many types of optical computers, especially those including holographic elements, employ transformations similar to Affine transformations. Therefore, techniques of the present invention may be implemented using optical computers or hybrid optical-electronic computers.

Thus, according to the present invention, the fractal method employing Affine transforms may be used to recognize images. This method proceeds as follows. A plurality of templates are stored in a memory device, which represent the images to be recognized. These templates may be preprocessed, or processed in parallel with the remainder of the procedure, in a corresponding manner. Image data, which may be high contrast line image, greyscale, or having a full color0s10.00v1P map, the greyscale being a unidimensional color map, is stored in the data processor, provided for performing the recognition function.

The image is preprocessed to extract various objects from the background, and to separate objects. This preprocessing may be performed in standard manner. The method of U.S. Pat. No. 5,136,659, incorporated herein by reference, may also be used. As a part of this preprocessing, a temporal analysis of the object through a series of image frames, is performed to provide four dimensional data about the object, i.e., the two dimensions from the image, a third image imputed from differing perspective views of the object, and time. Certain objects may be immediately recognized or classified, without further processing. Further, certain objects, without full classification or identification, may be “ignored” or subjected to a lesser level of final processing. During the classification processing, various objects may be selected for different types of processing, for example, people, automobiles, buildings, plants, etc.

After classification, and temporal analysis, an object for further processing is analyzed for degrees of freedom, i.e., joints of a person, moving parts of an object, etc. These degrees of freedom may then be corrected, e.g., the object itself altered, to change the image into a standard format, or the degree of freedom information processed with the object to allow mathematical normalization without actual change of the image.

The information describing the object image is stored. A plurality of addressable domains are generated from the stored image data, each of the domains representing a portion of the image information. As noted above, the entire image need not be represented, and therefore various objects separately analyzed. Further, only those parts of the image or object necessary for the recognition, need be analyzed. While it may be unknown which image components are unnecessary, sometimes this may be determined.

From the stored image data, a plurality of addressable mapped ranges are created, corresponding to different subsets of the stored image data. Creating these addressable mapped ranges, which should be uniquely addressable, also entails the step of executing, for each of the mapped ranges, a corresponding procedure upon the one of the subsets of the stored image data which corresponds to the mapped ranges. Identifiers are then assigned to corresponding ones of the mapped ranges, each of the identifiers specifying, for the corresponding mapped range, a procedure and a address of the corresponding subset of the stored image a.

To ensure comparability, the processing treatment of the template and the image data are analogous. Of course, template data may be stored in preprocessed form, so that the image data need only be processed according to the same rules. The domains are optionally each subjected to a transform, which may be a predetermined rotation, an inversion, a predetermined scaling, and a displacement. Because of the nature of these linear superposable transforms, the earliest iterations will include data about gross morphology, later iterations will include data about configuration, and latest iterations will include data about texture.

In addition, nonlinear alterations, and frequency, Gabor or wavelet transform preprocessing may be applied. A warping or other kind of transform may also be applied. These types of transforms are generally not included in Affine transform analysis, yet judiciously applied, may produce more rapid convergence, greater data storage efficiency, computational advantages or pattern matching advantages.

This transform is used to optimize the procedure, and also to conform the presentation of the image data with the template, or vice versa. Each of the domains need not be transformed the same way, and in fact it is the transform coefficients which are stored to describe the transformed object, so that differences in coefficients relate to differences in objects.

For each of the domains or transformed domains., as may be the case, the one of the mapped ranges which most closely corresponds according to predetermined criteria, is selected. The image is then represented as a set of the identifiers of the selected mapped ranges.

Finally, from the stored templates, a template is selected which most closely corresponds to the set of identifiers representing the image information. This matching process is optimized for the data type, which is a string of iterative transform coefficients, of a contractive transform.

It is preferred that, for each domain, a most closely corresponding one of the mapped ranges be selected. By performing analogous operations on a template and an unrecognized object in an image, a correspondence between the two may be determined. Thus, libraries of template image portions may be provided, with associated transform information, which may increase the computational efficiency of the system.

In selecting the most closely corresponding one of the mapped ranges, for each domain, the mapped range is selected which is the most similar, by a method which is appropriate, and may be, for example, secting minimum Hausdorff distance from the domain, selecting the highest cross-correlation with the domain, the minimum mean square error with the domain and selecting the highest fuzzy correlation with the domain, based on rules which may be predetermined. Neural network energy minimization may also yield the best fit, and other techniques may also be appropriate.

In particular, the step of selecting the most closely corresponding one of mapped ranges according to the minimum modified Hausdorff distance includes the step of selecting, for each domain, the mapped range with the minimum modified Hausdorff distance calculated as D[db,mrb]+D[1-db,1-mrb], where D is a distance calculated between a pair of sets of data each representative of an image, db is a domain, mrb is a mapped range, 1-db is the inverse of a domain, and 1-mrb is an inverse of a mapped range.

It is important that the selection criteria be tolerant to variations of the type seen in image data, e.g., video, so that like objects have similar transforms. Thus, the selection criteria is not particularly directed to optimal data compression, although the two criteria may coincide for some types of data.

In the case where the digital image data consists of a plurality of pixels, each having one of a plurality of associated color map values, the method includes a matching of the color map, which as stated above, encompasses a simple grey scale, natural color representation, and other color types. In such a case, the method is modified to optionally transform the color map values of the pixels of each domain by a function including at least one scaling function, for each axis of the color map, each of which may be the same or different, and selected to maximize the correspondence between the domains and ranges to which they are to be matched. For each of the domains, the one of the mapped ranges having color map pixel values is selected which most closely corresponds to the color map pixel values of the domain according to a predetermined criteria, wherein the step of representing the image color map information includes the substep of representing the image color map information as a set of values each including an identifier of the selected mapped range and the scaling functions. The correspondence method may be of any sort and, because of the added degree of complexity, may be a different method than that chosen for non-color images. The method of optimizing the correspondence may be minimizing the Hausdorff distance or other “relatedness” measurement between each main and the selected range. The recognition method concludes by selecting a most closely corresponding stored template, based on the identifier of the color map mapped range and the scaling functions, which is the recognized image.

Color information may have less relevance to pattern recognition than, for example, edge information, and therefore may be subjected to a lesser degree of analysis. The color information may also be analyzed separately, using a different technique.

EXAMPLE 24 Image Analysis

Alternatively to the object extraction, the image as a whole may be analyzed. In the case of moving images, the aforementioned method is further modified to accommodate time varying images. These images usually vary by small amounts between frames, and this allows a statistical improvement of the recognition function by compensating for a movement vector, as well as any other transformation of the image. This also allows a minimization of the processing necessary because redundant information between successive frames is not subject to the full degree of processing. Of course, if the image is substantially changed, then the statistical processing ceases, and a new recognition function may be begun, “flushing” the system of the old values. The basic method is thus modified by storing delayed image data information, i.e., a subsequent frame of a moving image. This represents an image of a moving object differing in time from the image data in the data processor.

A plurality of addressable further domains are generated from the stored delayed image data, each of the further domains representing a portion of the delayed image information, and corresponding to a domain. Thus, an analogous transform is conducted so that the further domains each are corresponding to a domain. A plurality of addressable mapped ranges corresponding to different subsets of the stored delayed image data are created from the stored delayed image data. The further domain and the domain are optionally matched by subjecting a further domain to a corresponding transform selected from the group consisting of a rotation, an inversion, a scaling, and a displacement, which corresponds to a transform applied to a corresponding domain, and a noncorresponding transform selected from the group consisting of a rotation, an inversion, a scaling, a translation which does not correspond to a transform applied to a corresponding domain. For each of the further domains or transformed further domains, the one of the mapped ranges is selected which most closely corresponds according to predetermined criteria. As stated above, these domains may also be subjected to corresponding and noncorresponding frequency domain processing transforms, Gabor transforms, and wavelet transforms.

A motion vector is then computed between one of the domain and the further domain, or the set of identifiers representing the image information and the set of identifiers representing the delayed image information, and the motion vector is stored. The further domain is compensated with the motion vector and a difference between the compensated further domain and the domain is computed. For each of the delayed domains, the one of the mapped ranges is selected which most closely corresponds according to predetermined criteria. The difference between the compensated further domain and the domain is represented as a set of difference identifiers of the selected mapping ranges and an associated motion vector.

This method is described with respect to FIGS. 27, 28 and 29. FIG. 27 is a basic flow diagram of the recognition system of the present invention. FIG. 28 provides a more detailed description, including substeps, which are included in the major steps shown in FIG. 27. Basically, the image, or a part thereof, is decomposed into a compressed coded version of the scene, by a modified fractal-based compression method. In particular, this differs from the prior compression algorithms in that only a part, preferably that part containing objects of interest, need be fully processed. Thus, if a background is known (identified) or uninteresting, it may be ignored. Further, the emphasis is on matching the available templates to produce an image recognition, not achieving a high degree of compression. Therefore, the image, or domains thereof, may be transformed as required in order to facilitate the matching of the templates. As with respect to single images, the templates are represented in analogous form, having been processed similarly, so that a comparison of the relatedness of an object in an image and the templates may be performed. In particular, if an oblique view of an object is presented, then either the object may be transformed to achieve a predicted front view, or the template transformed or specially selected to correspond to the oblique view. Further, once a recognition has taken place with a high degree of certainty, the system need only ensure that the scene has not changed, and need not continually fully process the data. This has implications where multiple recognition processes are occurring simultaneously, either in a single ot meet that required for de novo real time recognition of all aspects of all the objects or images.

In order to limit processing of portions of images, exclusionary criteria may be applied which allow truncation of processing when it is determined that an option is precluded or there exists a significantly higher probability alternative. The processing system may use primarily exclusionary criteria to select the best predictions, or after preselection, employ a highest probability selection system on the remaining choices.

FIG. 30 shows a flow diagram of a cartoon-like representation of an image recognition method of the present invention. It shows initially, an input image 3001, having a degree of complexity. A windowing function 3002 isolates the object from the background. A first order approximation of the image is generated 3003, here called a mapping region. The first order approximation is then subtracted from the initial image to produce a difference 3004. The first order error is then subjected, iteratively, to successive transform and subtract operations 3005 and 3006, until the error is acceptably small, at which point the input image is characterized by a series of codes, representing the first order approximation and the successive transforms, which are stored 3008. These codes are then compared with stored templates 3009. The comparisons are then analyzed to determine which template produces the highest correlation 3010, and the match probability is maximized 3011. The recognized image is then indicated as an output 3012.

This system is shown in FIG. 26, wherein a sensor 2602 provides data, which may be image data, to a control 2601. The control 2601 serves to control the plant 2603, which has an actuator. The plant 2603 may be a VCR or the like. The control 2601 has associated with it an intermediate sensor data storage unit 2611, which may be, for example a frame buffer or the like. The control 2601 also has associated with it a transform engine 2612, which may perform a reversible or irreversible transform on the data or stored data.

The system also has a template input 2610, which may receive data from the sensor 2602, if accompanied by identifying information. Thus, the pattern storage memory 2609 stores a pattern, such as an image pattern, along with an identifier.

The control 2601 also has an input device 2604, an on-screen display interface 2605, and a program memory 2606, for inputting instructions from a user, providing feedback to the user, and recording the result of the user interaction, respectively. Finally, a characterization network 2607 characterizes the sensor 2602 data, which may be provided directly from the sensor 2602 or preprocessing circuitry, or through the control 2601. A correlator 2608 correlates the output of the characterization network with the stored patterns, representing the templates from the template input 2610. The system therefore operates to recognize sensor patterns, based on the correlator 2608 output to the control 2601.

When analyzing objects in a sequence of images, a determination is made of the complexity of the difference based on a density of representation. In other words, the error between the movement and transform compensated delayed image and the image is quantified, to determine if the compensation is valid, or whether the scene is significantly changed. When the difference has a complexity below a predetermined or adaptive threshold, a template is selected, from the stored templates, which most closely corresponds or correlates with both the set of identifiers of the image data and the set of identifiers of the delayed image data, thus improving recognition accuracy, by allowing a statistical correlation or other technique. The threshold may be set based on an error analysis of the system to determine statistical significance or using other criteria. The threshold may also be adaptively determined based on the history of use of the machine and feedback. For example, if the two images both have a high correlation with one template, while a first of the images has a slightly higher correlation with another template, while the second image has a much lower correlation with that other template, then the system would score the first template as a better match to the first image, based on this differentiation. Thus, templates may be particularly selected to best differentiate similar images of objects.

EXAMPLE 25 Pattern Recognition System

The present system allows for the use of a pattern recognition subsystem for a controller which acts in accordance with a detected pattern. In image, audio and multimedia applications, different types of image processing may take place. First, various processing algorithms may take place in parallel, with an optimum result selected from the results of the various algorithms. Further, various processing schemes may be applied in sequence, with differing sequences applied to different data streams. These processing schemes may be commutative, i.e. yield approximately the same result regardless of the processing order, or may be highly order dependent, in which case a processed data stream must include information relating to the sequence of processing for interpretation.

Various exemplars may reside in a fragment library, for comparison with unidentified data. In the case of processing path dependent systems, an exemplar may be found in multiple forms based on the processing procedure, or in a small subset of corresponding libraries. In general, both lossless compression methods and lossy compression methods employed using high fidelity parameters to minimize loss may be processed to produce a relatively or almost unique result for each unknown data set, while lossy compression or processing methods will be particularly procedure sensitive, especially if differing strategies are employed. These differing strategies may be used to emphasize different features of the unknown data set in order to facilitate comparison. This technique is especially useful when the processing procedures are run in parallel, so that the latency penalty for redundant processing is minimized. Techniques available for this processing include vectorization, fractal processing, iterated function systems, spatial frequency processing (DCT-JPEG, MPEG, etc.), wavelet processing, Gabor transforms, neural nets (static or sequence of images), and other known techniques.

In a preferred embodiment, a spatial frequency or wavelet processing step is performed first, on static image data or a sequence of images, with a fractal domain processing step performed thereafter. This allows high frequency noise to be initially filtered: with subsequent fractal-based correlated noise detection and subtraction, therefore allowing cleanup without loss of high frequency detail. Preferably, before the fractal-based processing, which may be performed by a digital computer or optical processing apparatus, standard edge detection/object separation, e.g., high frequency filtering, contour mapping, artificial intelligence, etc. may be performed. A fractal transform is then performed on the image of a portion thereof, starting in a standardized manner, e.g. at a point of lowest complexity, or the epicenter of the largest feature for beginning a contractive transform. The processed image may then be matched with one or more databases to identify all or a portion of the image. Optionally, after a match has been found and/or confirmed by an operator, using the human interface system, the method is then optimized to minimize the errors and increase the efficiency of later matches. This may be performed by modifying the database record, or related records, as well as modifying the preprocessing algorithm. In a preferred embodiment, the image is processed piecemeal, on an object-by-object basis. Therefore, after an object has been processed, it is extracted from the image so that the remaining information may be processed. Of course, multiple objects may be processed in parallel. The exemplar database is preferably adaptive, so that new objects may be added as they are identified.

The present technology may also be used with a model-based exemplar database, wherein an image object is matched, based on a two dimensional projection, or analysis of a sequence of images, with a multidimensional model of an object. For example, the model may include volume, as well as multiple degrees of freedom of movement. Further, objects may also include “morphing” characteristics, which identify expected changes in an appearance of an object. Other types of characteristics may be included in conjunction with the exemplar in the database.

In a preferred embodiment, a model contained in a database includes a three or more dimensional representation of an object. These models include information processed by a fractal-based method to encode repetitive, transformed patterns in a plane, space, time, etc., as well as to include additional degrees of freedom, to compensate for changes in morphology of the object, to allow continuous object identification and tracking. Thus, once an object is identified, an expected change in that object will not necessitate a reidentification of the object. According to one embodiment, a fractal-like processing is executed by optical elements of an optical or optical hybrid computer. Further, in order to temporarily store an optical image, optically active biological molecules, such as bacteriorhodopsins, etc. may be used. Liquid crystals or other electrophotorefractive active materials may also used. These imagers may be simple two dimensional images, holograms, or other optical storage methods. A preferred holographic storage method is a volume phase hologram, which will transform an impressed image, based on hologram to image correlation. Thus, these models would be somewhat linear transform independent, and would likely show some (planar) transform relationship. Thus, an optical computer may be advantageous because of its high computational speed as compared to digital computers for image analysis, due to inherent parallelism and high inherent speed.

Because of the present limitations in speed of writing an image to optical recording media, especially holographic images, the preferred system includes a plurality of image storage elements, which are operated in parallel. It is noted that absolute accuracy of object identification is not required for “consumer” applications, and therefore partial match results may be considered useful. A plurality of partial results, when taken together, may also increase identification reliability. Critical applications generally differ in quantitative aspects rather than qualitatively, and therefore many aspects of the present invention may be applied to mission critical and other high reliability applications.

A preferred object identification method proceeds by first classifying an object in an image, e.g., “car”, “person”, “house”, etc. Then, based on the classification and object separation, an optimized preprocessing scheme is implemented, based on the classification. This classification preprocessing operates on the raw image data relating only to the object, separated from the background. Then, after the optimized preprocessing, a parallel recognition system would operate to extract unique features and to identify common features to be excluded from the comparison. This step could also identify variable features upon which identification should not be made because the distinctions are useless for the purpose. Thus, the object image at this point loses its relationship to the entire image, and the data reduction might be substantial, providing a compact data representation. The preferred algorithm has a tree structure, wherein the identification need only differentiate a few possibilities, and pass the result to another branch of the tree for further analysis, if necessary. Since the intermediate calculations may help in later computations, these should preferably be retained, in order to avoid duplicative analysis. Further, the order of analysis should be predetermined, even if arbitrary, so that once a useful intermediate calculation is identified, it may be passed in a regular, predictable manner to the next stage processing. Of course, one should not ignore that objects in the entire image may be correlated with one another, i.e. if one object is present, it would increase or decrease the likelihood of another object also being present. Further, temporal correlations should also be noted. Thus, the object identification need not proceed upon each object independently.

Based on time sequences of two-dimensional images, a three dimensional image representation may be constructed. Alternatively, based on various presumptions about extractable “objects” in a single or small group of two dimensional images, a hypothetical three dimensional object may be modeled, which may be later modified to reflect the actual image when an actual view of hidden surfaces is shown. Therefore, by one means or another a three dimensional model is created, having both volume and surface characteristics. Of course, since inner structure may never be seen, the model normally emphasized the surface structure, and is thus a so-called two-and-a-half dimensional surface model. Other non-integral dimension representations may also be useful, and fractal models may efficiently represent the information content of an image model.

When the source signal is an MPEG encoded datastream, it is advantageous to provide an exemplar database which does not require complete expansion of the encoded signal. Thus, the motion vector analysis performed by the MPEG encoder may form a part of the pattern recognition system. Of course, image sequence description formats other than MPEG may be better suited to pattern analysis and recognition tasks. For example, a system may transmit an interframe, by any suitable description method, as well as an object decomposed image in, e.g., fractal transform codes. The transmitted source material, other than interframes, is then transmitted as changes only, e.g. new objects, transforms of existing objects, translations of existing objects, etc.

Color coding may use even more extensive use of fractal compression technology with high compression ratios, because absolute accuracy is not necessary: rather photorealism and texture are paramount, and need not be authentic. Therefore, backgrounds with significant detail, which would require substantial data in a DCT type system, could be simply coded and decoded without loss of significant useful information. Important to the use of this method is to discriminate between background textures and foreground objects, and to encode each separately, optimizing the processing based on the type of object being processed.

EXAMPLE 26 Data Context Sensitive Computer Interface

The present example relates to a context sensitive computer interface in which a characteristic of the interface is modified based on a linguistic or informational content of a data object upon which the interface is operating. For example, a number of alternate feature sets may be made available based on the type of data which is being operated on by the user. For example, differing feature sets would be optimal for each scientific discipline, each type of financial or economic field, marketing, retail, distribution, manufacturing, administration, human resources, etc. Such an interface will make it possible to provide an extended and extensible suite of application modules customized for the user in general, and further adaptive to the particular use to which the user may be making of the apparatus. Thus, complex options particularly suited for the data at hand may be made available without inefficient interface searching, while inappropriate options are not presented. It is noted that this interface is responsive to the data, rather than the programming. Further, the data is analyzed for its meaning, rather than its type.

In a word processing environment, a document or section of a document is analyzed for the presence of particular words or phrases, or for the presence of concepts, interpretable by linguistic concepts. This context-sensitive functionality does not require an explicit definition by the user, but rather will be present even during an incidental occurrence of a recognized context. In accordance with other aspects of the present invention, each context related function may have various user levels, which are selected based on an imputed user level of the user. Thus, the interface program must actually interpret the text or context of the user document in order to select the most likely options for use.

Thus, if a user were to embed a table in a document, the available options would change to table-type options when the “active” portion of the document is at the table, i.e. within the viewable area, etc. Further, and more specifically, if the text and context of the table indicate that this is a financial table, financial options would be initially provided, and standard financial calculation functions immediately made available or performed, in contemplation of their prospective use. Similarly, if the data appears to be scientific, a different set of options would be initially available, and the standard scientific-type calculation functions be made available or performed. If the table relates to chemical or mechanical-type data, chemical or mechanical options might be made available, respectively. Embedded graphics, likewise, would be associated with graphics functions appropriate to the type of graphic. It is noted hat, due to the analysis of the content of the document, software having generic functionality may present as special purpose software, based on its actual use.

Thus, in a like manner, the system could determine the “style” of the document and automatically format the data in a predetermined manner to conform with general standards of presentations relating to the desired style. This is similar to style sheets of many programs, but they are self applying, and will, within the same document, be adaptive as the data changes context. Further, since the “styles” would be applied automatically, it would be relatively easy to alter them, requiring only a small amount of manual effort. This is so because the “keys” by which the system determines style could be stored, thus allowing redeterminations to be easily made. This context sensitivity could also assist in spelling and grammar checking, where different rules may apply, depending on the context.

The data object includes information, which might be text, arrays of numbers, arrays of formulas, graphics, or other data types. The system relates parts of the object to each other by “proximity” which could be linear, in the case of a text document, or otherwise, such as in the case of a hypertext document or spreadsheet. Those parts or elements of the object closest to each other, by whatever criteria, are presumed to be topically related, regardless of data type. Thus, if a paragraph of text is proximate to a table for numbers, then the type of numbers presumed to occupy the table would relate to the content of the proximate text. If the text relates to finance, i.e. uses financial-related terms, or series of words that often occur in financial contexts, the table would be presumed to be a financial table.

Once the context of the part of the object is determined, the system then acts based upon this context. The major act is the presentation of tailored menus. This means that if the context is financial, the menus available for use with the numeric table relate to financial tables or spreadsheets. Further, the proximate text would be subject to financial oriented spellcheck and financial oriented grammar or style check. If a graphics-option is selected proximate to the text and table, the menu options would presume a financial graph and present appropriate choices. Of course, the options need not be limited to a few types, and may be hybrid and/or adaptive to the style of the user. However, it is noted that the adaptive menus couldbe linked to a “corporate style”. Thus, communication styles could be dictated by a set of global rules for an organization. Of course, these a priori choices could be overridden.

An advantage of this system is that it allows a software system to include a wide range of functionality which remains “buried”, or relatively inaccessible, based on the context of usage. Thus, feature rich software would be considered more usable, and software could be provided in modular fashion. Since the system might allow a user to have potential access to many software modules, the system could also be linked to a license manager and per use billing system for rarely used modules, while allowing these to remain available on, e.g., a CD ROM. Thus, for example, a full integrated package could employ a single, “standard” interface which would not require task-switching programs, while avoiding presentation of the full range of features to the user at each juncture.

This system provides advantages over traditional systems by providing a non-standardized interface with a variable feature set which attains usability by adapting a subset of the available functionality based on the context of the data.

EXAMPLE 27 Group Aware Adaptive Computer Interface

The adaptive interface according to the present invention may be used in group computing applications. In such a case, the predictive functionality is applied to allow the interface to apply rules from one group member to a project, even when that group member has not contributed personally to a particular aspect. This is thus a type of intelligent agent technology, which, according to the present invention includes the characteristics of abstraction and extrapolation, rather than rule based analysis which would fail based on divergent circumstances. This differs from standard rule-based expert system because the intelligence applied is not necessarily “expert”, and may be applied in a relative fashion. Further, extracted user characteristics need not completely define a solution to a problem, and indeed, the use of such a technology in group situations presupposes that a contribution of a number of users is desirable, and therefore that the expertise of any given user is limited.

In order to ensure data integrity after the application or contingent application of user characteristics to a datastream, it is desirable to trace the evolution of data structures. This also allows for assistance in the organization and distribution of workgroup responsibilities. Thus, in a workgroup situation, the goal is not optimization of individual productivity, but rather optimization of the group result, including all levels of review after an initial phase is complete.

Thus, while an individual user may seek various shortcuts to achieve various results, the group would benefit by having available all information relating to the path taken to achieve that result. Further, the desired result may be modified according to the presumed actions of the group, so that the final product is pre-optimized for the group, rather than the individual. Thus, a group member may have his “rules” extracted from his actions, i.e. by neural net backpropagation of errors programming or fuzzy rule definition, to be presented for consideration by another group member. This strategy will allow “better” drafts by considering the predicted input of a member prior to review by that member. A user may further tailor the rules for a given project, and “distilled wisdom” from non-group members may also be employed, as in normal expert (AI) systems.

This rule-extraction technology as applied to workgroups is enhanced by the context sensitivity of the software, where the input of each group member may be weighted by considering the context. Again, this technique may be used to increase the efficiency of the primary author of a section of a project, as well as better defining the scope of responsibility of each member, while still respecting the input of other group members.

According to this workgroup rule extraction technology, points of conflict between group members are highlighted for resolution. As an adjunct to this resolution phase of a project, videoconferencing may be employed. Further, where a conflict of a similar type had occurred in the past, data relating to the resolution of that conflict, including recorded videoconference, may be retrieved and presented to one or more members of the workgroup. In this way, such conflicts may be resolved before it becomes adversarial. Thus, each group member may efficiently proceed independently, with only major issues requiring meetings and the like to resolve.

If a workgroup member disagrees with an imputed rule, either explicitly, by review of the rules, or implicitly, by a review of the results, the system will allow a review of all decisions influenced by that faulty rule, as well as a proposed correction. This may be addressed by any member of the group, but usually by the author of the section or the source of the rule will be the relevant reviewing individual. Rules may also be created by the group, rather than from a single individual. Such rules are more often explicitly defined, rather than derived from observation. Such group rules may also be subjected to adaptive forces, especially when overridden frequently.

EXAMPLE 28 Adaptive Interface Vehicular Control System

It is noted that, the adaptive user level interface is of use in uncontrolled environments, such as in a moving vehicle, especially for use by a driver. An intelligent system of the present invention would allow the driver of such a vehicle to execute control sequences, which may compensate for the limited ability to interact with an interface while driving. Thus, the driver need not explicitly control all individual elements, because the driver is assisted by an intelligent interface. Thus, for example, if it begins raining, the interface would predict the windshield wipers should be actuated, the windows and any roof opening closed, and the headlights activated. Thus, the driver could immediately assent to these actions, without individually actuating each control. In such a case, the screen interface, which may be a heads-up display, would provide a small number of choices, which may be simply selected. Further, under such conditions, there would likely be a large amount of mechanical jitter from the input device, which would be filtered to ease menu selection. Further, this jitter would indicate an unstable environment condition, which would cause the interface to present an appropriate display. A voice input may also be used.

EXAMPLE 29 Adaptive Interface Vehicular Control System

An integrated electronics system for an automobile is provided having control over engine, transmission, traction control, braking, suspension, collision avoidance, climate control, and audio systems. Steering and throttle may also be controlled. Based on driver preference and action patterns, the system may optimize the vehicle systems. For example, the vehicle may anticipate voluntary or road conditions based on implicit inputs of the user, thus readying vehicular systems prior to the actual encounter with certain conditions. Further, a user interface may be simplified, based on probable required functionality, thus limiting required attention by the driver in order to activate a particular control. By providing such an interface, controls normally inaccessible may be made accessible, without increasing mechanical complexity, e.g., functions normly controlled by computer may be accessed through a common user interface, rather than through dedicated manual controls.

The automobile control system may also include collision avoidance systems, which may include imaging sensors and radar or LIDAR ranging and velocity measurement. According to the present invention, a heads-up display or simplified graphic user interface in the dashboard or near the steering wheel presents predicted options to the driver. An auxiliary interface may also make certain options available for passengers.

According to another aspect of the present invention, an automobile positioning system is provided, which may be extraterrestrial, e.g., GPS, or terrestrial, e.g., cellular base station, LORAN, etc. Such a system is described in U.S. Pat. No. 5,390,125, incorporated herein by reference; see references cited therein. A controller in the automobile is provided with an itinerary for the vehicle travel. Based on position and itinerary, the vehicle may communicate with various services, such as food, fuel and lodging providers, to “negotiate” for business. The driver may be provided with customized “billboards”, directed to his demographics. Reservations and discounts may all be arranged while en-route. Communication between the automobile and the services is preferably provided by CDPD services, which is a cellular based 832 MHz band digital data transmission system. Therefore, an existing cell phone system or CDPD modem system may be employed for telecommunication. Preferably, a simple display is provided for presentation of commercial messages to the driver or passenger and for interacting with the service.

As a matter of practice, the service may be subsidized by the service providers, thus reducing the cost to the consumer. The extent of the subsidy may be determined by the amount of data transmitted or by the eventual consummation of the transaction negotiated.

Because of the positioning system, any variance from the itinerary may be transmitted to the service providers, so that reservations may be cancelled, or substitute services provided in a different location or at a different time.

The telecommunication system may also be used as an emergency system, to contact emergency services and/or police in the event of accident or distress. The transponder system may also be part of an antitheft system. The transponder may also be part of a vehicular maintenance and diagnostic system to ensure proper servicing and to help determine the nature of problems. Raw or processed data may be transmitted to a centralized station for full analysis and diagnosis. Because the vehicle need not be at the repair shop for diagnosis, problems may be analyzed earlier and based on extensive, objective sensor data.

EXAMPLE 30 Intelligent Internet Appliance

A further application of the present technologies is in a so-called “Internet appliance”. These devices typically are electronic devices which have a concrete function (i.e., do more than merely act as a generic server) and typically employ at least as a secondary interface, a web browser 3205. In addition, these devices provide a TCP/IP network connection and act as a web server, usually for a limited type of data. Therefore, in addition to any real human interface on the device, a web browser 3205 may be used as a virtual interface 3304.

According to the present invention, such an Internet Appliance is provided according to the present invention with advanced features, for example adaptivity to the user, to the environment, or intelligent algorithms which learn. In fact, a preferred embodiment provides 3301 a rather generic device which serves as a bridge between the Internet, a public packet switched network 3202 which employs TCP/IP, and a local area network 3213, for example in a residential, industrial or office environment. The device may further abstract the interface functions for a variety of other devices 3212 as nodes on either the Internet or local area network 3213, to provide a common control system and interface.

A preferred embodiment also encompasses certain other features which may be used as resources for the networked devices or as usable features of the device.

The Internet, or other wide area network, may be connected in any known manner, for example, X.25/ISDN D-channel, dial-up over POTS (e.g., v.34, v.90, v.91), ISDN, xDSL, ADSL, cable modem, frame relay, T1 line, ATM, or other communications system. Typically, a system is provided with either a commonly used access method, such as v.90 or ISDN, or a replaceable communications module with a generic interface. Such systems are well known.

The local area network 3213 is also well known, and may include, for example, as a physical layer, 10 Base T, 100 Base T, HomeRun (Cat. 3 twisted pair/telephone twisted pair/power line transmission, from Intel Corp., e.g., Intel 21145 device/Tut systems), Universal Serial Bus (USB), Firewire (IEEE-1394), optical fiber, or other known computer network. The protocol may be, for example, TCP/IP, IPX, ATM, USB, IEEE-1394, or other known or proprietary appropriate communications protocol.

While not required, a particular aspect of a preferred embodiment according to the present invention is the ability to interface “dumb” devices as nodes on the LAN 3213 with an intelligent device 3201, while allowing the user to interact primarily with the intelligent device 3201. This scheme therefore reduces redundancy and increases functionality.

Therefore, in an exemplary embodiment, an intelligent home is established, with most or all electrical appliances 3223 and electronic devices interfaced with the system, for example through the aforementioned Homerun system, using any of the supported physical layers. Each device is provided as a relatively simple control, for example, remotely controllable (or where applicable, dimmable) lights 3224, control over normal use and peak electrical demand of heavy appliances 3223, as well as inter-device communications for consumer electronics 3221. Therefore, the intelligent device acts as an external communications and control node for the entire network, and may, for example, control telephony 3214 functions in addition.

Exemplary devices to be controlled in a home include household appliances 3223, HVAC 3215, alarm systems 3217, consumer electronics 3221, and the like, and/or provide for communications purposes. An alarm system 3217 embodiment, for example, may employ a video camera input 3219 for capture and analysis of images, as well as motion or irregularity detection. The intelligent device 3201 may, for example, employ neural networks or other intelligent analysis technology for analyzing data patterns indicative of particular states. An alarm output may be produced, for example, through standard alarms, as well as through a telephone 3214 interface of the system.

The system may therefore set/control/monitor the status of any home-based device—oven, stove, alarm, washing machine, dryer, iron, lights, computer, oil/gas burner, thermostat 3222, location of automobiles 3218, camera, pump 3226 (pool, sump), sprinkler 3225, stereo/video systems, home surveillance system 3216. This may be especially important if the user is away from home for an extended period of time, or if he or she wants to change the schedule of something, or travel plans change. For a home surveillance system 3216, pattern recognition may be employed to monitor all sensors, including cameras, to detect abnormal patterns or changes in condition.

Thus, since the intelligent device incorporates a web server, the physical proximity of the user is not critical for interaction with the device, and all devices on the LAN 3213 may be controlled remotely, automatically, and in synchrony.

In one embodiment, the intelligent device includes a videoconferencing 3220/video capture system, including any or all known features for such systems, for example as described in the background of the invention. Therefore, in addition to a base level of functionality, such an embodiment would also likely include (a) telephony 3214 interface, (b) video capture, (c) video codec, (d) audio capture, (e) audio codec, (f) full duplex speakerphone, (g) video output, and (h) audio output.

In another embodiment, a speech interface is provided for interpreting human speech as an input and/or producing synthesized speech as an output. Therefore, such a device would include speech recognition and/or synthesis technologies, as well as a semantic data processor.

Preferably, the device allows use of a simplified web browser interface 3205, such as which may be supported by personal digital assistants (PDAs) and enhanced digital data cellular telephones, e.g., handheld device markup language (HDML). This, for example, allows a remote user to communicate through wireless networks 3211 or the like, and therefore avoids the need for a full personal computer as a human interface.

Advantageously, the device may be interfaced with a telephone 3214 communication system, allowing use as a voice and/or video message recorder, and allowing remote access to the stored information, either through a dialup connection and/or through the network. In this case, the intelligent device 3201 may act as a computer telephony interface, and all communications devices logically under this device act as “net phones”, i.e., voice communications devices which communicate over data networks. Therefore, all telephony control and computer telephony functions may be integrated into the device, for example, voice mail, auto-attendant, call center, and the like. Further, the Internet interface allows remote messaging and control over the telephony system, as well as virtual networking, Internet telephony, paging functions, and voice and data integration.

The intelligent device 3201 may also interface with various media electronics devices, and for example, may act as a “rights server” 3208 or other aspect of a copyright protection and royalty collection/enforcement system 3307. Typically, these functions entail e-commerce functions, and may require X.22 and/or XML communications and translations. In addition, such functions also typically involve encryption/decryption 3207, as well as key management, which are also preferably supported by the device. Such support may be in hardware or software.

Another aspect of the invention provides an index and/or catalog database 3204 for media information 3209 or media metadata 3210 information. Thus, data relating to a VCR tape or other recorded media may be subjected to search criteria without requiring access or contemporaneous analysis of the media content itself. Therefore, a preferred embodiment of the intelligent device includes mass storage and retrieval capability 3204, for example, magnetic disk, RW-CD, or RW-DVD. This mass storage and retrieval capability 3204 may be used, not only for databases, but also for computer software, media and content storage and retrieval 3303. Thus, the device may also serve as a video data recorder, capturing video data and storing it digitally, for example, employing the aforementioned video and audio codecs. In this case, it is preferable that the intelligent device 3201 also include a direct media access port 3203, for example a broadcast TV tuner, ATSC/HDTV tuner, cable tuner, DVD reader, CD reader, satellite video decoder, NTSC composite/S-VHS, and/or other type of media content information input 3302. With such storage, the intelligent device 3201 may also assume the standard functions of computer network servers, for example, file serving, print serving, fax serving, application serving, client/server application support, as well as traditional networking functions, such as bridging, routing, switching, virtual private network, voice-over-IP, firewall functions, remote access serving, and the like. It should also be apparent that the intelligent device 3201 may also serve as a personal computer 3206 itself, and thus does not require additional systems for basic functionality.

In a media recording system embodiment, the system preferably notifies the user if the “program”, i.e., instructions, are incomplete, ambiguous, or impossible to complete. For example, if a single channel selector is provided, no more than one channel may be monitored at a time. Further, where irreversible actions are necessary, the user is preferably informed and allowed to make a choice, for example, if lack of storage space forces a choice to be made between new and archival material. A conflict management system is provided which arbitrates between the conflicting demands, for example if a second user is programming the same device (for example, the VCR) to record a show at the same time.

Thus, it is apparent that the intelligent device 3201 according to this embodiment of the present invention may incorporate many different functions, some of which are defined purely by software and processing availability, and others by particular hardware devices for performing specific functions.

Another aspect of the invention defines a special training mode of the intelligent device, which allows the user to improve the functionality of the system by ensuring that any intelligence algorithms will correctly operate in an anticipated and/or desired manner. In this mode, responses of the user are provoked which indicate user preferences, preferably in a manner which resolves ambiguities encountered with prior data sets. Thus, where the system identifies a situation where a decision is difficult, e.g., where the data analysis does not output any selected actions which will likely correspond to the user desires or preferences, or where ex post facto the user indicates that an inappropriate choice was made, the particular data structures may be stored and abstracted for later presentation to the user. In this case, such structures are presented by the system to the user, during a training session, to train the system relating to the desired response to particular data environments. In this way, the user is not necessarily burdened with training tasks during normal use of the device, and opportunities for such training are not lost. Where the system is untrained, and an “intelligent” response or mode of operation cannot be resolved, a default mode of operation may be defined. Further, such a default mode is preferably always available, at the request of the user, thus allowing use where an adaptive system is undesired or difficult to employ.

In a television application, the Internet appliance preferably has access to an electronic program guide (EPG). Such EPG systems are known, and typically provide an efficient staring point for user programming. These EPG may be provided as an embedded signal in a broadcast stream, through a dial-up network, through the internet, or on distribution media, such as CD-ROM, OCR scanning of TV-Guide (or the like) or other known means. EPGs contain a concise semantic description of program content, which typically is both sufficient for user evaluation, and brief enough for rapid evaluation. The system may therefore analyze user preferences in this semantic space and provide adaptive presentation of elements of the EPG to the user. Of course, a media data stream analysis embodiment of the invention, as disclosed above, may be used in conjunction with or in lieu of the EPG system.

The system preferably maintains an updated index of available data. Thus, newly acquired data is added to the index, and deleted data is purged from the index. The system preferably compares new data to previously encountered data, to avoid redundant processing. For example, the system preferably recognizes events/programs that have previously been recorded, and checks to determine whether they are still in the index. In this context, the user is preferably provided with low-level file maintenance tools, for example to manually control the addition or deletion of data, which is then correctly represented in the index.

Because the Internet appliance is connected to the Internet, so-called multicasts may be monitored for correspondence with user preferences. Therefore, it is understood that the operation of the present invention is not limited to traditional television broadcasts, and that streaming video and audio, as well as stored images, sound files (e.g., MIDI, MP3, A2B, RealAudio), text, and multimedia streams may be analyzed based on the adaptive principles presented herein 3305.

The system may also integrate Internet data with other types of data, for example providing access to stored or static data corresponding to a data stream. The retrieval and storage of such data may also be adaptively controlled in accordance with the present invention. Thus, it is expressly understood that the intelligent device may act as a “VCR” (albeit not necessarily employing a known type of videocassette tape), to record media 3306.

The Internet appliance may also operate autonomously, capturing data which corresponds to user preferences and profiles, thus reducing latency for the user, and potentially shifting data transfers to off-peak periods. Such a system operates in this mode as a so-called “agent” system. Likewise, the device may also be linked to other intelligent devices, to provide an intelligent interaction therebetween.

The preferred user interface maintains user levels constant over long periods, i.e., not rapidly adaptive, to allow for quick accessing over a low bandwidth connection, such as a telephone, or using succinct displays, such as might be found on a personal digital assistant. Thus, the user can rely on memory of the interface functionality and layout to reduce data transmissions and reduce search time. In one embodiment, the interface may be “forced” to a particular type, as either a permanent interface, or as a starting point for adaptivity. Thus, the user may be provided with an interface design mode of operation.

The user interaction with each “device”, which may be real or virtual (implemented as a software construct in a relatively general purpose computer), is preferably carefully designed for each device. A common user interface paradigm is preferably provided for corresponding functions, while the user interface is preferably optimized for dealing with the specific functions of each particular device. Thus, a similar user interface and screen layout is employed for functions that are the same across a variety of devices. In this regard, it is an aspect of an embodiment of the invention to translate user interface systems, even in a high level state, to other forms. Thus, in a multi-brand environment, related components may have native interfaces that are both well developed and distinctly different. Therefore, the present invention allows for a translation or remapping of the functionality into a common paradigm. Where aspects cannot be adequately translated, the native interface may be presented to the user.

REFERENCES

-   “32-bit Floating-Point DSP Processors”, EDN, Nov. 7, 1991, pp.     127–146. -   “A New Class of Markov Processes for Image Encoding”, School of     Mathematics, Georgia Inst. of Technology (1988), pp. 14–32. -   “A show and tell of the QBIC technology—Query By Image Content     (QBIC)”, IBM QBIC Almaden web site, pp. 1–4. -   “ABI WHAP, Web Hypertext Applications Processor,”     http://alphabase.com/abi3/whapinfo.html#profiling, (1996, Jul. 11). -   “AdForce Feature Set”,     http://www.imgis.com/index.html/core/p2--2html (1997, Apr. 11). -   “Bar Code Programs VCR”, Design News, Feb. 1, 1988, 26. -   “C-Cube CL550 JPEG Image Compression Processor”, Preliminary Data     Book, August 1991, and addendum dated Nov. 20, 1991. -   “Chaos & Non-Linear Models in Economics”. -   “Chaos Theory in the Financial Markets. Applying Fractals, Fuzzy     Logic, Genetic Algorithms”. -   “Construction of Fractal Objects with Iterated Function Systems”,     Siggraph '85 Proceedings, 19(3):271–278 (1985). -   “Data Compression: Pntng by Numbrs”, The Economist, May 21, 1988. -   “EMC² Pushes Video Rental By Satellite”, Electronic Engineering     Times, Dec. 2, 1991, p. 1, p. 98. -   “Evolutionary Economics & Chaos Theory”. -   “Finger Painting”, Information Display 12, p. 18, 1981. -   “Four Eyes”, MIT Media Lab web site; pp. 1–2. -   “Fractal Geometry-Understanding Chaos”, Georgia Tech Alumni     Magazine, p. 16 (Spring 1986). -   “Fractal Modelling of Biological Structures”, Perspectives in     Biological Dynamics and Theoretical Medicine, Koslow, Mandell,     Shlesinger, eds., Annals of New York Academy of Sciences, vol. 504,     179–194 (date unknown). -   “Fraal Modelling of Real World Images, Lecture Notes for Fractals:     Introduction, Basics and Perspectives”, Siggraph (1987). -   “Fractals Yield High Compression”; Electronic Engineering Times;     Sep. 30, 1991; p. 39. -   “Fractals—A Geometry of Nature”, Georgia Institute of Technology     Research Horizons; p. 9 (Spring 1986). -   “Frequently asked questions about visual information retrieval”,     Virage Incorporated web site; pp. 1–3. -   “How to find the best value in VCRs”, Consumer Reports, March 1988,     135–141. -   “IBM Ultimedia Manager 1.1 and Clinet Search”. IBM software web     site, pp. 1–4. -   “Image Compression Using Fractals and Wavelets”, Final Report for     the Phase II Contract Sponsored by the Office of Naval Research,     Contract No. N00014-91-C-0117, Netrologic Inc., San Diego, Calif.     (Jun. 2, 1993). -   “Image Detection and Registration”, Digital Image Processing, Pratt,     Wiley. New York, 1991. -   “IPRO,” http://www.ipro.com/, Internet profiles Corporation Home and     other Web Pages (1996, Jul. 11). -   “Jacob Methodology” @     http://WWCSAI.diepa.unipa.it/research/projects/jacob/jacob-method.html. -   “Low-Cost VCRs: More For Less”, Consumer Reports, March 1990,     168–172. -   “Machine Now Reads, enters Information 25 Times Faster Than Human     Keyboard Operators”, Information Display 9, p. 18 (1981). -   “Market Analysis. Applying Chaos Theory to Investment & Economics”. -   “Media Planning is Redefined in a New Era of Online Advertising,” PR     Newswire, (1996, Feb. 5). -   “MPEG: A Video Compression Standard for Multimedia Applications”, Le     Gall, Communications of the ACM, vol. 34, No. 4, April 1991, pp.     47–58. -   “My Yahoo! news summary for My Yahoo! Quotes”, http://my.yahoo.con,     (1997, Jan. 27). -   “NetGravity Announces Adserver 2.1”,     http://www.netgravity.com/news/pressre/launch21.html (1997, Apr.     11). -   “Netscape & NetGravity: Any Questions?”, http://www.netgravity.com/,     (1996, Jul. 11). -   “Network Site Main”,     http://www.doubleclick.net/frames/general/nets2set.htm (1997, Apr.     11). -   “New Beetle Cursor Director Escapes All Surface Constraints”,     Information Display 10, p. 12, 1984. -   “Nielsen Views VCRs”, Television Digest, Jun. 23, 1988, 15. -   “Photobook”, MIT Media Lab web site; Aug. 7, 1996; pp. 1–2. -   “Profiting from Chaos. Using Chaos Theory for Market Timing, Stock     Selection & Option”. -   “Real Media,” http://www.realmedia.com/index.html, (1996, Jul. 11). -   “Scanner Converts Materials to Electronic Files for PCs”, IEEE CG&A,     December 1984, p. 76. -   “Spe Analysis”, Digital Image Processing, Pratt, Wiley, New York,     1991. -   “The Front Page”, http://live.excite.com/?aBb (1997, Jan. 27) and     (1997, Apr. 11). -   “The Highs and Lows of Nielsen Homevideo Index”, Marketing & Media     Decisions, November 1985, 84–86+. -   “The Pointcast Network,” http:/www.pointcast.com/, (1996, Spring). -   “The Power of PenPoint”, Can et al., 1991, p. 39, Chapter 13, pp.     258–260. -   “The QBIC Project”, IBM QBIC Almaden web site, home page. -   “The Quest for ‘User Friendly’”, U.S. News & World Report, Jun. 13,     1988, 54–56. -   “The Smart House: Human Factors in Home Automation”, Human Factors     in Practice, December 1990, 1–36. -   “VCR, Camcorder Trends”, Television Digest, Vol. 29, Mar. 20, 1989,     16. -   “VCR's: A Look At The Top Of The Line”, Consumer Reports, March     1989, 167–170. -   “VHS Videocassette Recorders”, Consumer Guide, 1990, 17–20. -   “Virage—Visual Information Retrieval”, Virage Incorporated, home     page. -   “Virage Products”, Virage Incorporated web site; pp. 1–2. -   “Visual Information Retrieval: A Virage Perspective Revision 3”,     Virage Incorporated web site; 1995; pp. 1–13. -   “Visual Pattern Recognition by Moment Invariants”, IRE Trans.     Inform. Theory, vol. 8, February 1962, pp. 179–187. -   “Voice Recognition and Speech Processing”, Elektor Electronics,     September 1985, pp. 56–57. -   “Welcome to Lycos,” http://www.lycos.com, (1997, Jan. 27). -   “Workshop Report: NSF—ARPA Workshop on Visual Information Management     Systems”, Virage Incorporated web. site; pp. 1–15. -   “WWW.amazon.com”. -   “WWW.firefly.com”. -   Abadi, M., et al, “Authentication and Delegation with Smart-cards”,     Oct. 22, 1990, revised Jul. 30, 1992 Report 67, Systems Research     Center, Digital Equipment Corp., Palo Alto, Calif. -   Abatemarco, Fred, “From the Editor”, Popular Science, September     1992, p. 4 Abe, S., Y. Tonomura, Systems and Computers in Japan,     vol. 24, No. 7, “Scene Retrieval Method Using Temporal Condition     Changes”, pp. 92–101, 1993. -   Abedini, Kamran, “An Ergonomically-improved Remote Control Unit     Design”, Interface '87 Proceedings, 375–380. -   Abedini, Kamran, and Hadad, George, “Guidelines For Designing Better     VCRs”, Report No. IME 462, Feb. 4, 1987. -   Advertisement for “TV Decision,” CableVision, Aug. 4, 1986. -   Aleksander, I., “Guide to Pattern Recognition Using Random-Access     Memories”, Computers and Digital Techniques, 2(1):29–40 (Feb; 1979). -   American National Standard, “Financial Institution RetI Message     Authentication”, ANSI X9.19 1986. -   American National Standard, “Interchange Message Specification for     Debit and Credit Card Message Exchange Among Financial     Institutions”, ANSI X9.2-1988. -   Anderson, F., W. Christiansen, B. Kortegaard. “Real Time, Video     Image Centroid Tracker”, Apr. 16–20, 1990. -   Anderson, Ross J., “UEPS —A Second Generation Electronic Wallet”,     Proc. of the Second European Symposium on Research in Computer     Security (ESORICS), Touluse, France, pp. 411–418, Touluse, France. -   Anderson, Ross, “Why Cryptosystems Fail”, Proc. 1st Conf. Computer     and Comm. Security, pp. 215–227, November 1993. -   Anson, L., “Fractal Image Compression”, Byte, October 1993, pp.     195–202; “Fractal Compression Goes On-Line”, Byte, September 1993. -   Anson, L., M. Barnsley; “Graphics Compression Technology”; SunWorld;     pp. 43–52 (October 1991). -   Antonofs, M., “Stay Tuned for Smart TV,” Popular Science, November     1990, pp. 62–65. -   Appriou, A., “Interet des theories de l'incertain en fusion de     donnees”, Colloque International sur le Radar Paris, 24–28 avril     1989. -   Appriou, A., “Procedure d'aide a la decision multi-informateurs.     Applications a la classification multi-capteurs de cibles”,     Symposium de l'Avionics Panel (AGARD) Turquie, 25–29 avril 1988. -   Arman et al., “Feature Management for Large Video Databases”, 1993.     (Abstract Only). -   Arman et al., “Image Processing on Compressed Data for Large Video     Databases”, Proc. of First ACM Int. Conf. on Multimedia, Anaheim,     Calif., 1–6 August 1993, pp. 267–272. -   Arman et al., “Image Processing on Encoded Video Sequences”, ACM     Multimedia Systems Journal, to appear 1994. -   Arndt, T., “A Survey of Recent Research in Image Database     Management”, IEEE Publication No. TH0330-1/90/0000/0092, pp. 92–97,     1990. -   Arrow, K. J., “Social choice and individual valves”, John Wiley and     Sons Inc. (1963). -   Arrowsmith, D K & C M Place: “An Introduction to Dynamical Systems”,     Cambridge University Press, Cambridge, 1990. -   Asian Technology Information Program (ATIP) Report: ATIP95.65: Human     Computer Interface International, July 1995 Yokohama. -   Astrom, K. J., and B. Wittenmark, “Adaptive Control”, Addison-Wesley     Publishing Company (1989) pp. 105–215. -   Astrom, K. J., T. Hagglund, “Automatic Tuning of PID Controllers”,     Instrument Society of America, Research Triangle Park, N.C. (1988)     pp. 105–132. -   Atkinson, Terry, “VCR Programming: Making Li Easier Using Bar     Codes”. -   Is Bach, J. R., C. Fuller, A. Gupta, A. Hampapur, B. Horowitz, R.     Humphrey, R. C. Jain, and C. Shu. Virage image search engine: an     open framework for image management. In Symposium on Electronic     Imaging: Science and Technology—Storage & Retrieval for Image and     Video Databases IV, pages 76–87. IS&T/SPIE, 1996. -   Bagley, H. & Sloan, J., “Optical Processing: Ready For Machine     Vision?”, Photonics Spectra, August 1993, pp. 101–106. -   Bains, S., “Trained Neural Network Recognizes Faces”, Laser Focus     World, June, 1993, pp. 26–28. -   Baker, Gregory L., & Jerry P Gollub: “Chaotic Dynamics: An     Introduction”, Cambridge University Press, Cambridge, 1990. -   Baldwin, William, “Just the Bare Facts, Please”, Forbes Magazine,     Dec. 12, 1988. -   Ballard, D. H., and Brown, C. M., Computer Vision, Prentice Hall,     Englewood Cliffs, N.J. (1982); Optical Engineering 28:5 (May     1988)(Special Issue on product inspection). -   Barber et al. “Ultimedia Manager: Query by Image Content and it's     Applications” IEE, 1994, pp. 424–429, January 1994. -   Barnsley et al., “A Better Way to Compress Images”, Byte, January     1988, pp. 213–225. -   Barnsley et al., “Chaotic Compression”, Computer Graphics World,     November 1987. -   Barnsley et al., “Harnessing Chaos For Images Systhesis”, Computer     Graphics, 22(4):131–140 (August, 1988). -   Barnsley et al., “Hidden Variable Fractal Interpolation Functions”,     School of Mathematics, Georgia Institute of Technology, Atlanta, Ga.     30332, July, 1986. -   Barnsley, M., L. Anson, “Graphics Compression Technology, SunWorld,     October 1991, pp. 42–52. -   Barnsley, M. F., A. Jacquin, F. Malassenet, L. Reuter & A. D. Sloan,     ‘Harnessing chaos for image synthesis’, Computer Graphics, vol 22 no     4 pp 131–140, (August, 1988). -   Barnsley, M. F., A. E. Jacquin, ‘Application of recurrent iterated     function systems to images’, Visual Comm. and Image Processing, vol     SPIE-1001, 1988. -   Barnsley, M. F., “Fractals Everywhere”, Academic Press, Boston,     Mass., 1988. -   Barnsley, M. F., and Demko, S., “Iterated Function Systems and The     Global Construction of Fractals”, Proc. R. Soc. Lond., A399:243–275     (1985). -   Barnsley, M. F., Ervin, V., Hardin, D., Lancaster, J., “Solution of     an Inverse Problem for Fractals and Other Sets”, Proc. Natl. Acad.     Sci. U.S.A., 83:1975–1977 (April 1986). -   Barros, et al. “Indexing Multispectral Images for Content-Based     Retrieval”, Proc. 23rd AIPR Workshop on Image and Information     Retrieval, Proc. 23rd Workshop, Washington, D.C., October 1994, pp.     25–36. -   Batchelor, B. G., “Pattern Recognition, Ideas in Practice”, Plenum     Press, London and New York, (1978). -   Batchelor, B. G., “Practical Approach to Pattern Classification”,     Plenum Press, London and New York, (1974). -   Baxes, Gregory A., “Digital Signal Processing, A Practical Primer”,     Prentice-Hall, Englewood Cliffs, N.J. (1984). -   Beaumont J M, “Image data compression using fractal techniques”,     British Telecom Technological Journal 9(4):93–108 (1991). -   Belkin, N. J., Croft, W. B., “Information Filtering And Information     Retrieval: Two Sides of the Same Coin?”, Communications of the ACM,     December 1992, vol. 35, No. 12, pp. 29–38. -   Bellman, R. E., L. A. Zadeh, “Decision making in a fuzzy     environment”, Management Science, 17(4) (December 1970). -   Bender, M., “EFTS: Electronic Funds Transfer Systems”, Kennikat     Press, Port Washington, N.Y., pp. 43–46 1975. -   Bensch, U., “VPV—VIDEOTEXT PROGRAMS VIDEORECORDER”, IEEE     Transactions on Consumer Electronics, Vol. 34, No. 3, 788–792     (1988). -   Berger, Ivan, “Secrets of the Universals”, Video, February 1989,     45–47+. -   Beringer, D. B., “A Comparative Evaluation of Calculator Watch Data     Entry Technologies: Keyboards to Chalkboards”, Applied Ergonomics,     December 1985, 275–278. -   Berniker, M., “Nielsen plans Internet Service,” Broadcasting &     Cable, 125(30):34 (1995, Jul. 24). -   Berry, Deanne, et al. In an Apr. 10, 1990 news release, Symantec     announced a new version of MORE (TM). -   Berry, Jonathan, “A Potent New Tool for Selling Database Marketing”,     Business Week, Sep. 5, 1994, pp. 34–40. -   Berry, M V, I C Persival & N O Weiss: “Dynamical Chaos”, The Royal     Society, London, 1987, Proceedings of a Royal Society Discussion     Meeting held on 4 & 5 Feb. 1987. -   Bestler, Caitlin: Flexible Data Structures and Interface Rituals For     Rapid Development of OSD Applications; 93 NCTA Tech. Papers; Jun. 6,     1993; pp. 223–236. -   Betts, M., “Sentry cuts access to naughty bits,” Computers and     Security, vol. 14, No. 7, p. 615 (1995). -   Bhatnagar, R. K., L. N. Kamal, “Handling uncertain information: a     review of numeric and non-numeric methods”, Uncertainty in     Artificial Intelligence, L. N. Kamal and J. F. Lemmer, Eds. (1986). -   Bier, E. A. et al. “MMM: A User Interface Architecture for Shared     Editors on a Single Screen,” Proceedings of the ACM Symposium on     User Interface Software and Technology, Nov. 11–13, 1991, p. 79. -   Bimbo et al., “Sequence Retrieval by Contents through Spatio     Temporal Indexing”, IEEE on CD-ROM, pp. 88–92, Aug. 24, 1993. -   Bimbo, A. D., et at, “3-D Visual Query Language for Image     Databases”, Journal Of Visual Languages & Computing, 1992, pp.     257–271. -   Binaghi, E., et at, “Indexing and Fuzzy Logic Based Retrieval of     Color Images”, Visual Database Systems, II, 1992, pp. 79–92. -   Binaghi, E., et al., “A Knowledge-Based Environment for Assessment     of Color Similarity”, Proc. 2nd Annual Conference on Topics for AI,     pp. 268–285 (1990). -   Bishop, Edward W., and Guinness, G. Victor Jr., “Human Factors     Interaction with Industrial Design”, Human Factors, 8(4):279–289     (August 1966). -   Blair, D., R. Pollack, “La logique du choix collectif” Pour 1 a     Science (1983). -   Bolot, J.; Turletti, T. & Wakeman, I.; “Scalable Feedback Control     for Multicast Video Distribution In the Internet”, Computer     Communication Review, vol. 24, No. 4 Oct. 1994, Proceedings of     SIGCOMM 94, pp. 58–67. -   Bos et al., “SmartCash: a Practical Electronic Payment System”, pp.     1–8; August 1990. -   Boy, Guy A., Intelligent Assistant Systems, Harcourt Brace     Jovanovich, 1991, uses the term “Intelligent Assistant Systems”. -   Bristol, E. H., & T. W. Kraus, “Life with Pattern Adaptation”,     Proceedings 1984 American Control Conference, pp. 888–892, San     Diego, Calif. (1984). -   Brown, Edward, “Human Factors Concepts For Management”, Proceedings     of the Human Factors Society, 1973, 372–375. -   Brown, Robert: “Statistical Forecasting for Inventory Control”,     McGraw-Hill Book Co., New York, 1958. -   Bruce, J W, & P J Giblin: “Curves and Singularities”, Cambridge     University Press, Cambridge, 1992. -   Brugliera, Vito, “Digital On-Screen Display—A New Technology for the     Consumer Interface”, Symposium Record Cable Sessions. Jun. 11, 1993,     pp. 571–586. -   Bulkeley, Debra, “The Smartest House in America”, Design News, Oct.     19, 1987, 56–61. -   Burk et al, “Value Exchange Systems Enabling Security and     Unobservability”, Computers & Security, 9 1990, pp. 715–721. -   Burr, D. J., “A Neural Network Digit Recognizer”, Proceedings of the     1986 IEEE International Conference of Systems, Man and Cybernetics,     Atlanta, Ga., pp. 1621–1625. -   Bursky, D., “Improved DSP ICs Eye New Horizons”, Electronic Design,     Nov. 11, 1993, pp. 69–82. -   Bussey, H. E., et al., “Service Architecture, Prototype Description,     and Network Implications of a Personalized Information Grazing     Service,” IEEE Multiple Facets of Integration Conference     Proceedings, vol. 3, No. Conf. 9, Jun. 3, 1990, pp. 1046–1053. -   Byte Magazine, January 1988. -   Caffery, B., “Fractal Compression Breakthrough for Multimedia     Applications”, Inside, Oct. 9, 1991. -   Card, Stuart K., “A Method for Calculating Performance times for     Users of Interactive Computing Systems”, IEEE, 1979, 653–658. -   Carlson, Mark A., “Design Goals for an Effective User Interface”,     Human Interfacing with Instruments, Electro/82 Proceedings,     3/1/1–3/1/4. -   Carpenter, G. A., S. Grossberg, “The Art of Adaptive Pattern     Recognition by a Self-Organizing Neural Network”, IEEE Computer.     March 1988, pp. 77–88. -   Carroll, Paul B., “High Tech Gear Draws Cries of “Uncle”, Wall     Street Journal, Apr. 27, 1988, 29. -   Casasent, D., and Tescher, A., Eds., “Hybrid Image and Signal     Processing II”, Proc. SPIE Technical Symposium, April 1990, Orlando     Fla. 1297 (1990). -   Casasent, D., et al., “General I and Q Data Processing on a     Multichannel AO System”, Applied Optics, 25(18):3217–24 (Sep. 15,     1986). -   Casasent, D., Photonics Spectra, November 1991, pp. 134–140. -   Casdagli, Martin, & Stephen Eubank: “Nonlinear Modelling and     Forecasting”, Addison-Wesley Publishing Co., Redwood City, 1992. -   Case Study: The CIRRUS Banking Network, Comm. ACM 8, 28 pp.     7970–8078, August 1985. -   Caudill, M., “Neural Networks Primer-Part III”, AI Expert, June     1988, pp. 53–59. -   Cawkell, A. E., “Current Activities in Image Processing Part III:     Indexing Image Collections”, CRITique, vol. 4, No. 8, May 1992, pp.     1–11, ALSIB, London. -   Chalmers, M., Chitson, P., “Bead: Explorations In Information     Visualization”, 15th Ann. Int'l SIGIR 92/Denmark-June 1992, pp.     330–337. -   Chang et al., “Image Information Systems: Where Do We Go From     Here?”, IEEE Transactions on Knowledge and Data Engineering, vol. 4,     No. 5, October 1992, pp. 431–442. -   Chang et al., “Intelligent Database Retrieval by Visual Reasoning”,     PROC Fourteenth Annual International Computer Software and     Application Conference, 31 Oct.–1 November 1990, pp. 459–464. -   Chang, C., “Retrieving the Most Similar Symbolic Pictures from     Pictorial Databases”, Information Processing & Management, vol., No.     5, 1992. -   Chang, C., et al, “Retrieval of Similar Pictures on Pictorial     Databases”, Pattern Recognition, vol. 24, No. 7, 1991, pp. 675–680. -   Chang, N. S., et al., “Picture Query Languages for Pictorial     Data-Base Systems”, Computer vol. 14, No. 11, pp. 23–33 (November     1981). -   Chang, N. S., et al., “Query-by-Pictorial Example”, IEEE     Transactions on Software Engineering, vol. SE-6, No. 6, pp. 519–524     (November 1980). -   Chang, S., et al, “An Intelligent Image Database System”, IEEE     Transactions On Software Engineering, vol. 14, No. 5, May 1988, pp.     681–688. -   Chang, S.-F, Compressed-domain techniques for image/video indexing     and manipulation. In Proceedings, I.E.E.E. International Conference     on Image Processing, Washington, D.C., October 1995. invited paper     to the special session on Digital Library and Video on Demand. -   Chang, S.-K., Principles of Pictorial Information Systems Design.     Prentice Hall, 1989. -   Chang, S.-K., Q. Y. Shi, and C. Y. Yan. “Iconic indexing by 2-D     strings”. IEEE Trans. On Pattern Analysis And Machine Intelligence,     vol. 9, No. 3, May 1987, pp. 413–428. -   Chang, Yuh-Lin, Zeng, Wenjun, Kamel, Ibrahim, Alonso, Rafael,     “Integrated Image and Speech Analysis for Content-Based Video     Indexing”. -   Chao, J. J., E. Drakopoulos, C. C. Lee, “An evidential reasoning     approach to distributed multiple hypothesis detection”, Proceedings     of the 20th Conference on decision and control, Los Angeles, Calif.,     December 1987. -   Chao, T.-H.; Hegblom, E.; Lau, B.; Stoner, W. W.; Miceli, W. J.,     “Optoelectronically implemented neural network with a wavelet     preprocessor”, Proceedings of the SPIE—The International Society for     Optical Engineering, 2026:472–82(1993). -   Chapra, Steven C, & Raymond P Canale: “Numerical Methods for     Engineers”, McGraw-Hill Book Co., New York, 1988. -   Charles, S., et al, “Using Depictive Queries to Search Pictorial     Databases”, Human Computer Interaction, 1990, pp. 493–498. -   Chassery, J. M., et al., “An Interactive Segmentation Method Based     on Contextual Color and Shape Criterion”, IEEE Transactions on     Pattern Analysis and Machine Intelligence, vol. PAMI-6, No. 6,     (November 1984). -   Chaum et al, “Untraceable Electronic Cash”, Advances in Cryptology,     1988, pp. 319–327. -   Chaum et al; “Achieving Electronic Privacy”, Scientific American,     pp. 319–327; 1988. -   Chaum, D. “Security without Identification: Card Computers to Make     Big Brother Obsolete”, Communications of the ACM, 28(10), October     1985, pp. 1030–1044. -   Chaum, D. “Untraceable Electronic Mail, Return Addresses, and     Digital Pseudonyms”, Communications of the ACM, vol. No. 2,     February, 1981. -   Chaum, D., “Achieving Electronic Privacy”, Scientific American,     August 1992, pp. 96–101. -   Chaum, D. L. et al.; “Implementing Capability-Based Protection Using     Encryption”; Electronics Research Laboratory, College of     Engineering, University of California, Berkeley, Calif.; Jul. 17,     1978. -   Chen et al., “Adaptive Coding of Monochrome and Color Images”,     November 1977, pp. 1285–1292. -   Chen, Z., et al, “Computer Vision for Robust 3D Aircraft Recognition     with Fast Library Search”, Pattern Recognition, vol. 24, No. 5, pp.     375–390, 1991, printed in Great Britain. -   Cheong, C. K.; Aizawa, K.; Saito, T.; Hatori, M., “Adaptive edge     detection with fractal dimension”, Transactions of the Institute of     Electronics, Information and Communication Engineers D-II,     J76D-II(11):2459–63 (1993). -   Child, Jeff, “H.324 Paves Road For Mainstream Video Telephony”,     Computer Design, January 1997, pp. 107–110. -   Chua, T.-S., S.-K. Lim, and H.-K. Pung. Content-based retrieval of     segmented images. In Proc. ACM Intern. Conf. Multimedia, October     1994. -   Cobb, Nathan, “I don't get it”, Boston Sunday Globe Magazine, Mar.     25, 1990, 23–29. -   Cohen, Danny; “Computerized Commerce”; ISI Reprint Series     ISI/RS-89/243; October, 1989; Reprinted from Information Processing     89, Proceedings of the IFIP World Computer Congress, held Aug.     28-Sep. 1, 1989. -   Cohen, Danny; “Electronic Commerce”; University of Southern     California, Information Sciences Institute, Research Report     ISI/RR-89-244; October, 1989. -   Cohen, R., “FullPixelSearch Helps Users Locate Graphics”, MacWeek,     Aug. 23, 1993, p. 77. -   Commaford, C., “User-Resonsive Software Must Anticipate Our Needs”,     PC Week, May 24, 1993. -   Common European Newsletter, Multimedia Content manipulation and     Management, http://ww.esat.kuleuven.ac.be/˜konijin/ . . . -   CompuServe Information Service Users Guide, CompuServe     International, 1986, pp. 109–114. -   Computer Shopper, November 1994, “Internet for Profit”, pp. 180–182,     187, 190–192, 522–528, 532, 534. -   Computer Visions, Graphics, and Image Processing 1987, 37:54–115. -   Computer, Vol. 28(9), September 1995. -   Computers and Biomedical Research 5, 388–410 (1972). -   Compuvid Sales Manual (date unknown). -   Consumer Digest advertisement: Xpand Your TV's Capability:     Fall/Winter 1992; p. 215. -   Cooper, L. N., “A Possible Organization of Animal Memory and     Learning”, Nobel 24, (1973), Collective Properties of Physical     Systems, pp. 252–264. -   Corporate Overview, Virage Incorporated web site; pp. 1–4. -   Corripio, A. B., “Tuning of Industrial Control Systems”, Instrument     Society of America, Research Triangle Park, N.C. (1990) pp. 65–81. -   Cox, Ingemar J., et al., “PicHunter: Bayesian Relevance Feedback for     Image Retrieval,” Proc. of the ICPR '96, IEEE, pp. 361–369. -   Crawford et al., “Adaptive Pattern Recognition Applied To An Expert     System For Fault Diagnosis In Telecommunications Equipment”, pp.     10/1–8 (Inspec. Abstract No. 86C010699, Inspec IEE (London) & IEE     Coll. on “Adaptive Filters”, Digest No. 76, Oct. 10, 1985). -   Cutting, D. R.; Karger, D. R.; Pedersen, J. O. & Tukey, J. W.     “Scatter/Gather: A Cluster-based Approach to Browsing Large Document     Collections”, 15 Ann. Int'l SIGIR '92, ACM, 1992, pp. 318–329. -   Cvitanovic, Predrag: “Universality in Chaos”, Adam Hilger, Bristol,     1989. -   Daly, Donal: “Expert Systems Introduced”, Chartwell-Bratt, Lund,     1988. -   Damashek, M., Gauging Similarity via N-Grams: Language-Independent     Sorting, Categorization, and Retrieval of Text, pp. 1–11, Jan. 24,     1995. -   Danielsson, Erik, et al.; “Computer Architectures for Pictorial Inf.     Systems”; IEEE Computer, November, 1981; pp. 53–67. -   Data Partner 1.0 Simplifies DB Query Routines, PC Week, Sep. 14,     1992, pp. 55 & 58. -   Davis, Andrew W., “Hi Grandma!: Is It Time for TV Set POTS     Videoconferencing?”, Advanced Imaging, pp. 45–49 (March 1997). -   Davis, Andrew W., “The Video Answering Machine: Intel ProShare's     Next Step”, Advanced Imaging, pp. 28–30 (March 1997). -   Davis, Fred, “The Great Look-and-Feel Debate”, A+, 5:9–11 (July     1987). -   Deering, S.; Estrin, D.; Farinacci, D.; Jacobson, V.; Liu, C.; Wei,     L; “An Architecture for Wide-Area Multicast Routing”, Computer     Communication Review, vol. 24, No. 4, October 1994, Proceedings of     SIGCOMM 94, pp. 126–135. -   Dehning, Waltraud, Essig Heidrun, and Maass, Susanne, The Adaptation     of Virtual Man-Computer Interfaces to User Requirements in Dialogs,     Germany: Springer-Verlag, 1981. -   Dempster, A. P., “A generalization of Bayesian inference”, Journal     of the Royal Statistical Society, Vol. 30, Series B (1968). -   Dempster, A. P., “Upper and lower probabilities induced by a     multivalued mapping”, Annals of mathematical Statistics, no. 38     (1967). -   Denker; 1984 International Test Conf., October 1984, Philadelphia,     Pa.; pp. 558–563. -   Derra, Skip, “Researchers Use Fractal Geometry”, Research and     Development Magazine, March 1988. -   Diggle, Peter J: “Time Series: A Biostatistical Introduction”,     Clarendon Press, Oxford, 1990. -   DivX standard. -   Donnelley, J. E., “WWW media distribution via Hopewise Reliabe     Multicast,” Computer Networks and ISDN Systems, vol. 27, No. 6, pp.     81–788 (April, 1995). -   Donovan, J., “Intel/IBM's Audio-Video Kernel”, Byte, December, 1991,     pp. 177–202. -   Drazin, P G: “Nonlinear System”, Cambridge University Press,     Cambridge, 1992. -   Dubois, D., “Modeles mathematiques de l'imprecis et de l'incertain     en vue d'applications aux techniques d'aide a la decision”, Doctoral     Thesis, University of Grenoble (1983). -   Dubois, D., N. Prade, “Combination of uncertainty with belief     functions: a reexamination”, Proceedings 9th International Joint     Conference on Artificial Intelligence, Los Angeles (1985). -   Dubois, D., N. Prade, “Fuzzy sets and systems-Theory and     applications”, Academic Press, New York (1980). -   Dubois, D., N. Prade, “Theorie des possibilites: application a la     representation des connaissances en informatique”, Masson, Paris     (1985). -   Dubois, D.; “Modeles mathematiques de l'imprecis et de l'incertain     en vue d'applications aux techniques d'aide a la decision”; Doctoral     Thesis, University of Grenoble (1983). -   Duda, R. O., P. E. Hart, M. J. Nilsson, “Subjective Bayesian methods     for rule-based inference systems”. Technical Note 124-Artificial     Intelligence Center-SRI International. -   Dukach, Semyon, “SNPP: A Simple Network Payment Protocol”, MIT     Laboratory for Computer Science, Cambridge, Mass. 1993. -   Dukach, Seymon; Prototype Implementation of the SNPP Protocol;     allspic.lcs.mit.edu; 1992. -   Dunning, B. B., “Self-Learning Data-Base For Automated Fault     Localization”, IEEE, 1979, pp. 155–157. -   EDN, May 11, 1995, pp. 40–106. -   Edwards, John R., “Q&A: Integrated Software with Macros and an     Intelligent Assistant”, Byte Magazine, January 1986, vol. 11, Issue     1, pp. 120–122, critiques the Intelligent Assistant by Symantec     Corporation. -   Ehrenreich, S. L., “Computer Abbreviations—Evidence and Synthesis”,     Human Factors, 27(2):143–155 (April 1985). -   Ekeland, Ivar: “Mathematics and the Unexpected”, The University of     Chicago Press, Chicago, 1988 -   Falconer, Kenneth: “Fractal Geometry”, John Wiley & Sons,     Chichester, 1990. -   Electronic Engineering Times (EET), Oct. 28, 1991, p. 62. -   Electronic Engineering Times, Oct. 28, 1991, p. 62, “IBM Points a     New Way”. -   Elliott, “Watch—Grab—Arrange See: Thinking with Motion Images via     Streams and Collages”, Ph.D. Thesis, MIT, February 1993. -   Elofson, G. and Konsynski, B., “Delegation Technologies:     Environmental Scanning with Intelligent Agents”, Journal of     Management Information Systems, Summer 1991, vol. 8, Issue 1, pp.     37–62. -   Elton, J., “An Ergodic Theorem for Iterated Maps”, Journal of     Ergodic Theory and Dynamical Systems, 7 (1987). -   Even et al; “Electronic Wallet”, pp. 383–386; 1983. -   Faloutsos, C., et at, “Efficient and Effective Querying by Image     Content”, Journal of Intelligent Information Systems:Integrating     Artificial Intelligence and Database Technologies, vol. 3–4, No. 3,     July 1994, pp. 231–262. -   Farrelle, Paul M. and Jain, Anil K., “Recursive Block Coding—A New     Approach to Transform Coding”, IEEE Transactions on Communications,     Corn. 34(2) (February 1986). -   Fassihi, Theresa & Bishop, Nancy, “Cable Guide Courting National     Advertisers,” Adweek, Aug. 8, 1988. -   Fisher Y, “Fractal image compression”, Siggraph 92. -   Fitzpatrick, J. M., J. J. Grefenstette, D. Van Gucht, “Image     Registration by Genetic Search”, Conf. Proc., IEEE Southeastcon     1984, pp. 460–464. -   Flickner, et al. “Query by Image and Video Content, the QBIC     System”, IEEE Computer 28(9); 23–32, 1995. -   Foley, J. D., Wallace, V. L., Chan, P., “The Human Factor of     Computer Graphics Interaction Techniques”, IEEE CG&A, November 1984,     pp. 13–48. -   Foltz, P. W., Dumais, S. T., “Personalized Information Delivery: An     Analysis Of Information Filtering Methods”, Communications of the     ACM, December 1992, vol. 35, No. 12, pp. 51–60. -   Fractal Image Compression Michael F. Barnsley and Lyman P. Hurd ISBN     0-86720-457-5, ca. 250 pp. -   Fractal Image Compression: Theory and Application, Yuval Fisher     (ed.), Springer Verlag, New York, 1995. ISBN number 0-387-94211-4. -   Fractal Modelling of Biological Structures, School of Mathematics,     Georgia Institute of Technology (date unknown). -   Franklin, Gene F—, J David Powell & Abbas Emami-Naeini: “Feedback     Control of Dynamic Systems”, Addison-Wesley Publishing Co. Reading,     1994. -   Freeman, W. T., et al, “The Design and Use of Steerable Filters”,     IEEE Transactions on Pattern Analysis and Machine Intelligence, vol.     15, No. 9, September 1991, pp. 891–906. -   Friedman, M. B., “An Eye Gaze Controlled Keyboard”, Proceedings of     the 2nd International Conference on Rehabilitation Engineering,     1984, 446–447. -   Fu, Sequential Methods in Pattern Recognition and Machine Learning,     Academic, NY, N.Y. 1968. -   Fua, P. V., “ing probability density functions in the framework of     evidential reasoning Uncertainty in knowledge based systems”, B.     Bouchon, R. R. Yager, Eds. Springer Verlag (1987). -   Garretson, R., “IBM Adds ‘Drawing Assistant’ Design Tool to Graphics     Series”, PC Week, Aug. 13, 1985, vol. 2, Issue 32, p. 8. -   Gautama, S., D'Haeyer, J., “Learning Relational Models of Shape: A     Study of the Hypergraph Formalism”. -   Gautama, S., D'Haeyer, J. P. F., “Context Driven Matching in     Structural Pattern Recognition”. -   Gellert, W, H Kustner, M Hellwich & H Kastner: “The VNR Concise     Encyclopedia of Mathematics”, Van Nostrand Reinhols Co., New York,     1975. -   Gelman, A. D., et al.: A Store-And-Forward Architecture For     Video-On-Demand Service; ICC 91 Conf.; June 1991; pp. 842–846. -   George E P Box & Gwilym M Jenkins: “Time Series Analysis:     Forecasting and Control”, Holden Day, San Francisco, 1976. -   Gessler, S. and Kotulla A., “PDAs as mobile WWW browsers,” Computer     Networks and ISDN Systems, vol. 28, No. 1–2, pp. 53–59 (December     1995). -   Gevers, T., et al, “Enigma: An Image Retrieval System”, IEEE 11th     IAPR International Conference On Pattern Recognition, 1992, pp.     697–700. -   Gevers, T., et al, “Indexing of Images by Pictorial Information”,     Visual Database Systems, II, 1992 IFIP, pp. 93–101. -   Gifford, D., “Notes on Community Information Systems”, MIT LCS     TM-419, December 1989. -   Gifford, David K.; “Cryptographic Sealing for Information Secrecy     and Authentication”; Stanford University and Xerox Palo Alto     Research Center; Communication of the ACM; vol. 25, No. 4; April,     1982. -   Gifford, David K.; “Digital Active Advertising”; U.S. patent     application Ser. No. 08/168,519; filed Dec. 16, 1993. -   Gilfoil, D., and Mauro, C. L., “Integrating Human Factors and     Design: Matching Human Factors Methods up to Product     Development”, C. L. Mauro Assoc., Inc., 1–7. -   Gleick, James, “Chaos—Making a New Science”, Heinemann, London,     1988. -   Gligor, Virgil D. et al.; “Object Migration and Authentication”;     IEEE Transactions on Software Engineering; vol. SE-5, No. 6;     November, 1979. -   Glinert-Stevens, Susan, “Microsoft Publisher: Desktop Wizardry”,PC     Sources, February, 1992, vol. 3, Issue 2, p. 357. -   Goble, C., et al, “The Manchester Multimedia Information System”,     Proceedings of IEEE Conference, Eurographics Workshop, April, 1991,     pp. 244–268. -   Gogoussis et al., Proc. SPIE Intl. Soc. Opt. Eng., November 1984,     Cambridge, Mass., pp. 121–127. -   Goldberg, Cheryl, “IBM Drawing Assistant: Graphics for the EGA”, PC     Magazine, Dec. 24, 1985, vol. 4, Issue 2 p. 255. -   Gong et al, “An Image Database System with Content Capturing and     Fast Image Indexing Abilities”, PROC of the International Conference     on Multimedia Computing and Systems, pp. 121–130 May 19, 1994. -   Gong et al. “An Image Database System with Content Capturing and     Fast Image Indexing Abilities” IEEE, 1994, pp. 121–130, May 1994. -   Gonzalez et al., Digital Image Processing, Addison-Wesley, Reading,     Mass., 1977. -   Gonzalez, Rafael C., “Digital Image Processing”, Addison-Wesley,     Reading, Mass. (1987). -   Gonzalez, Rafael C., “Digital Image Processing”, Addison-Wesley,     Reading, Mass. (1987). -   Gould, John D., Boies, Stephen J., Meluson, Antonia, Rasammy,     Marwan, and Vosburgh, Ann Marie, “Entry and Selection Methods For     Specifying Dates”. Human Factors, 32(2):199–214 (April 1989). -   Graf S, “Barnsley's Scheme for the Fractal Encoding of Images”,     Journal Of Complexity, V8, 72–78 (1992). -   Great Presentations advertisement: Remote, Remote; 1987; p. 32H. -   Green, Lee, “Thermo Tech: Here's a common sense guide to the new     thinking thermostats”, Popular Mechanics, October 1985, 155–159. -   Grosky, W., et al, “A Pictorial Index Mechanism for Model-based     Matching”, Data 7 Knowledge Engineering 8, 1992, pp. 309–327. -   Grosky, W., et at, “Index-based Object Recognition in Pictorial Data     Management”, -   Computer Vision, 1990, pp. 416–436. -   Grossberg, S., G. Carpenter, “A Massively Parallel Architecture for     a Self-Organizing Neural Pattern Recognition Machine,” Computer     Vision, Graphics, and Image Processing (1987, 37, 54–115), pp.     252–315. -   Grudin, Jonathan, “The Case Against User Interface Consistency”, MCC     Technical Report Number ACA-HI-002-89, January 1989. -   Gudivada, V. N., and V. V. Raghavan. Design and evaluation of     algorithms for image retrieval by spatial similarity. ACM Trans. on     Information Systems. 13(2), April 1995. -   Gudivada, V., et al, “A Spatial Similarity Measure for Image     Database Applications”, Technical Report 91-1, Department of     Computer Science, Jackson, Miss., 39217, 1990–1991. -   Guenther, O., and A. Buchmann. Research issues in spatial databases.     In ACM SIGMOD Record, volume 19, December 1990. -   Gullichsen E., E. Chang, “Pattern Classification by Neural Network:     An Experiment System for Icon Recognition,” ICNN Proceeding on     Neural Networks, March 1987, pp. IV-725-32. -   Gupta, Amarnath; Weymount, Terry & Jain, Ramesh, “Semantic Queries     With Pictures: The VIMSYS Model”, Proceedings of the 17th     International Conference on Very Large Data Bases, pp. 69–79,     Barona, September, 1991. -   Hafner, J., H. S. Sawhney, W. Equitz, M. Flickner, and W. Niblack.     Efficient color histogram indexing for quadratic form distance     functions. IEEE Trans. Pattern Anal. Machine Intell., July 1995. -   Haines, R. W., “HVAC Systems Design Handbook”, TAB Professional and     Reference Books, Blue Ridge Summit, Pa. (1988) pp. 170–177. -   Harris, C. J., & S. A. Billings, “Self-Tuning and Adaptive Control:     Theory and Applications”, Peter Peregrinus LTD (1981) pp. 20–33. -   Harty et al., “Case Study: The VISA Transaction Processing System,”     1988. -   Haruki, K. et al., “Pattern Recognition of Handwritten Phonetic     Japanese Alphabet Characters”, International Joint Conference on     Neural Networks, Washington, D.C., January 1990, pp. II-515 to     II-518. -   Harvey, Michael G., and Rothe, James T., “VideoCassette Recorders:     Their Impact on Viewers and Advertisers”, Journal of Advertising,     25:19–29 (December/January 1985). -   Hasegawa, J., et al, “Intelligent Retrieval of Chest X-Ray Image     Database Using Sketches”, System And Computers In Japan, 1989, pp.     29–42. -   Hawkins, William J., “Super Remotes”, Popular Science, February     1989, 76–77. -   Hayashi, Y., et al., “Alphanumeric Character Recognition Using a     Connectionist Model with the Pocket Algorithm”, Proceedings of the     International Joint Conference on Neural Networks, Washington, D.C.     Jun. 18–22, 1989, vol. 2, pp. 606–613. -   Hayes, H. I.; Solka, J. L.; Priebe, C. E.; “Parallel computation of     fractal dimension”, Proceedings of the SPIE—The International     Society for Optical Engineering, 1962:219–30 (1993). -   Hendrix, Gary G. and Walter, Brett A., “The Intelligent Assistant:     Technical Considerations Involved in Designing Q&A's     Natural-language Interface”, Byte Magazine, December 1987, vol. 12,     Issue 14, p. 251. -   Henke, Lucy L., and Donohue, Thomas R., “Functional Displacement of     Traditional TV Viewing by VCR Owners”, Journal of Advertising     Research, 29:18–24 (April–May 1989). -   Hinton et al., “Boltzmann Machines: Constraint Satisfaction Networks     that Learn”, Tech. Report CMU-CS-85–119, Carnegie-Mellon Univ, May     1984. -   Hirata, et al. “Query by Visual Example, Content Based Image     Retrieval” Advance in Database Technology-EDBT '92, Springer-Verlag,     Berlin 1992, pp. 56–71 Hirata, K., et al, “Query by Visual Example     Content Based Image Retrieval”, Advances In Database Technology,     March, 1992, pp. 57–71. -   Hirzalla et al., “A Multimedia Query User Interface”, IEEE on     CD-ROM, pp. 590–593, Sep. 5, 1995. -   Hirzinger, G., Landzettel, K., “Sensory Feedback Structures for     Robots with Supervised Learning”, IEEE Conf. on Robotics and     Automation, St. Louis, March 1985. -   Hoare, F.; de Jager, G., “Neural networks for extracting features of     objects in images as a pre-processing stage to pattern     classification”, Proceedings of the 1992 South African Symposium on     Communications and Signal Processing. COMSIG '92 (Cat.     No.92TH0482-0). Inggs, M. (Ed.), p. 239–42 (1992). -   Hoban, Phoebe, “Stacking the Decks”, New York, Feb. 16, 1987, 20:14. -   Hoffberg, Linda I, “AN IMPROVED HUMAN FACTORED INTERFACE FOR     PROGRAMMABLE DEVICES: A CASE STUDY OF THE VCR” Master's Thesis,     Tufts University (Master of Sciences in Engineering Design,     November, 1990). -   Hoffberg, Linda I., “Designing a Programmable Interface for a Video     Cassette Recorder (VCR) to Meet a User's Needs”, Interface 91 pp.     346–351 (1991). -   Hoffberg, Linda I., “Designing User Interface Guidelines For     Time-Shift Programming of a Video Cassette Recorder (VCR)”, Proc. of     the Human Factors Soc. 35th Ann. Mtg. pp. 501–504 (1991). -   Hoffman, D. L. et al., “A New Marketing Paradigm for Electronic     Commerce,” (1996, -   Feb. 19), http://www2000.ogsm.vanderbilt.edu     novak/new.marketing.paradigm.html. -   Hollatz, S. A., “Digital image compression with two-dimensional     affine fractal interpolation functions”, Department of Mathematics     and Statistics, University of Minnesota-Duluth, Technical Report     91-2. -   Hong Kong Enterprise advertisement: Two Innovative New Consumer     Products From SVI; November 1988; p. 379. -   Hongjiang, et al., Digital Libraries, “A Video Database System for     Digital Libraries”, pp. 253–264, May 1994. -   Hooge, Charles, “Fuzzy logic Extends Pattern Recognition Beyond     Neural Networks”, Vision Systems Design, January 1998, pp. 32–37. -   Hopfield et al., “Computing with Neural Circuits: A Model”, Science,     233:625–633 (8 Aug. 1986). -   Hopfield, “Neural Networks and Physical Systems with Emergent     Collective Computational Abilities”, Proc. Natl. Acad. Sci. USA,     79:2554–2558 (April 1982). -   Hopfield, “Neurons with graded response have collective     computational properties like those of two-state neurons”, Proc.     Natl. Acad. Sci. USA, 81:3088–3092 (May 1984). -   Hopfield; “Neural Networks and Physical Systems with Emergent     Collective Computational Abilities”; Proc. Natl. Acad. Sci. USA;     79:2554–2558 (April 1982). -   Horgan, H., “Medical Electronics”, IEEE Spectrum, January 1984, pp.     90–93. -   Hou et al., “Medical Image Retrieval by Spatial Features”, IEEE on     CD-ROM, pp. 1364–1369, Oct. 18, 1992. -   Howard, Bill, “Point and Shoot Devices”, PC Magazine, 6:95–97     (August 1987). -   Hsu et al., “Pattern Recognition Experiments in the Mandala/Cosine     Domain”, IEEE Transactions on Pattern Analysis and Machine     Intelligence, vol. PAMI-5, No. 5, September 1983, pp. 512–520. -   Hu et al., “Pattern Recognition by Moment Invariants”. Proc. IRE,     vol. 49, 1961, p. 1428. -   Hunter, Jane, “The Application of Metadata Standards to Video     Indexing”     http://www.dtsc.edu.au/RDU/staff/jane-hunter/EuroDL/final.html     (<Dec. 24, 1998). -   Hurtgen, B.; Buttgen, P., “Fractal approach to low rate video     coding”, Proceedings of the SPIE—The International Society for     Optical Engineering, 2094(pt.1):120–31(1993). -   Hutheesing, H., “Interactivity for the passive”, Forbes magazine     Dec. 6, 1993 (@ Forbes Inc. 1993) (2 pages). -   IEEE Communications Magazine; vol. 32, No. 5, May 1994 New York,     N.Y., US, pp. 68–80, XP 000451097 Chang et al “An Open Systems     Approach to Video on Demand”. IEEE-1394. -   Iino et al., “An Object-Oriented Model for Spatio-Temporal     Synchronization of Multimedia Information”, May, 1994. -   Information describing BroadVision One-to-One Application System:     “Overview,” p. 1; Further Resources on One-To-One Marketing, p. 1;     BroadVision Unleashes the Power of the Internet with Personalized     Marketing and Selling, pp. 1–3; Frequently Asked Questions, pp. 1–3;     Products, p. 1; BroadVision One-To-One(.TM.), pp. 1–2; Dynamic     Command Center, p. 1; Architecture that Scales, pp. 1–2; Technology,     pp. 1; Creating a New Medium for Marketing and Selling BroadVision     One-To-One and the World Wide Web a White Paper, pp. 1–15;     http://www.broadvision.com (1996, January–March). -   Information Network Institute, Carnegie Mellon University, Internet     Billing Server, Prototype Scope Document, Oct. 14, 1993. -   Information Processing 71, North-Holland Publishing Company (1972)     pp. 1530–1533. -   Ingemar J. Cox et al., “Target Testing and the Pic Hunter Bayesian     Multimedia Retrieval System,” Proc. of the 3d Forum on Research and     Technology Advances in Digital Libraries, ADL '96, IEEE, pp. 66–75. -   Intel Corporation, iPower Technology, Marketing Brochure, date     unown. -   Intuit Corp. Quicken User's Guide, “Paying Bills Electronically”,     pp. 171–192; undated. -   Ioka, M., “A Method of Defining the Similarity of Images on the     Basis of Color Information”, Bulletin Of The National Museum Of     Ethnology Special Issue, pp. 229–244, No. 17, November 1992. -   Irven, Judith H., et al., “Multi-Media Information Services: A     Laboratory Study”, IEEE Communications Magazine, vol. 26, No. 6,     June, 1988, pp. 24–44. -   Ishizuka, M., “Inference methods based on extended Dempster and     Shafer's theory for problems with uncertainty/fuzziness”, New     Generation Computing, 1:159–168 (1983), Ohmsha, Ltd, and Springer     Verlag. -   Ishizuka, M., “Inference methods based on extended Dempster and     Shafer's theory for problems with uncertainty/fuzziness”, New     Generation Computing, 1:159–168 (1983), Ohmsha, Ltd., and Springer     Verlag. -   ISO/IEC JTC1/SC29/WG11 N1733, MPEG97, July 1997, “MPEG-7 Context and     Objectives (v.4-Stockholm)”. -   ISO/IEC JTC1/SC29/WG11 N1735, MPEG97, July 1997-Stockholm, MPEG-7     Applications Document”. -   ISO/IEC JTC1/SC29/NVG11 N1920, MPEG97, October 1997 “MPEG-7 Context     and Objectives (v.5-Fribourg)”. -   ISO/IEC JTC1/SC29/WG11 N2460, MPEG98, October 1998 “MPEG-7 Context     and Objectives (v.10-Atlantic City)”. -   ISO/IEC JTC1/SC29/WG11 N2461, MPEG98, October 1998-Atlantic City,     “MPEG-7 Requirements”. -   ISO/IEC JTC1/SC29/WG11 N2462, MPEG98, October 1998-Atlantic City,     “MPEG-7 Applications”. -   ISO/IEC JTC1/SC29/WG11 N2467, MPEG98, October 1998-Atlantic City,     “MPEG-7 Content Set”. -   Iyengar et al., “Codes Designs for Image Browsing”, 1994. -   Jackel, L. D., H. P. Graf, J. S. Denker, D. Henderson and I. Guyon,     “An Application of Neural Net Chips: Handwritten Digit Recognition,”     ICNN Proceeding, 1988, pp. II-107–15. -   Jacobs, Charles E., Finkelstein, Adam, Salesin, David H., “Fast     Multiresolution Image Querying”, Department of Computer Science,     University of Washington, Seattle Wash. -   Jacobs, E. W., Y. Fisher and R. D. Boss. “Image Compression: A study     of the Iterated Transform Method.” Signal Processing 29, (1992)     25–263. -   Jacquin, A., “Image Coding Based on a Fractal Theory of Iterated     Contractive Image Transformations” p. 18, January 1992 (Vol 1     Issue 1) of IEEE Trans on Image Processing. -   Jacquin, A., “A Fractal Theory of Iterated Markov Operators with     Applications to Digital Image Coding”, PhD Thesis, Georgia Tech,     1989. -   Jacquin, A., ‘Fractal image coding based on a theory of iterated     contractive image transformations’, Proc. SPIE Visual Communications     and Image Processing, 1990, pages 27–239. -   Jacquin, A. E. ‘A novel fractal block-coding technique for digital     images’, Proc. ICASSP 1990. -   Jane Pauley Special, NBC TV News Transcript, Jul. 17, 1990, 10:00     PM. -   Jean, J. S. N., et al., “Input Representation and Output Voting     Considerations for Handwritten Numeral Recognition with     Backpropagation”, International Joint Conference on Neural Networks,     Washington, D.C., January 1990, pp. 1–408 to 1–411. -   Jeffrey, R. J., “The logic of decision”, The University of Chicago     Press, Ltd., London (1983)(2nd Ed.). -   Jim Binkley & Leslie Young, Rama: An Architecture for Internet     Information Filtering, Journal of Intelligent Information Systems:     Integrating Artificial Intelligence and Database Technologies, vol.     5, No. 2, September 1995, pp. 81–99. -   Jones, R., “Digital's World-Wide Web server: A case study,” Computer     Networks and ISDN Systems, vol. 27, No. 2, pp. 297–306 (November     1994). -   JPL New Technology Report NPO-20213, Nasa Tech Brief Vol. 22, No. 4,     Item #156 (April 1998). -   Kato, T., “A Sketch Retrieval Method for Full Color Image     Database-Query by Visual Example”, IEEE, Publication No.     0-8186-2910-X/92, 1992, pp. 530–533. -   Kato, T., “Intelligent Visual Interaction with Image Database     Systems Toward the Multimedia Personal Interface”, Journal Of     Information Processing, vol. 14, No. 2, 1991, pp. 134–143. -   Kato, T., et al, “A Cognitive Approach Interaction”. International     Conference Of Multimedia Information Systems, January, 1991, pp.     109–119. -   Kato, T., et al, “Trademark: Multimedia Database with Abstracted     Representation on Knowledge Base”, Proceedings Of The Second     International Symposium On Interoperable Information Systems, pp.     245–252, November 1988. -   Kato, T., et al, “Trademark: Multimedia Image Database System with     Intelligent Human Interface”, System And Computers In Japan, 1990,     pp. 33–46. -   Kaufmann, A., “Introduction a la theorie des sous-ensembles flous”,     Vol. 1, 2 et 3-Masson-Paris (1975). -   Kaye, Brian H: “A Random Walk Through Fractal Dimensions”, VCH     Verlagsgesellschaft, Weinheim, 1989. -   Keeney, R. L., B. Raiffa, “Decisions with multiple objectives:     Preferences and value tradeoffs”, John Wiley and Sons, New York     (1976). -   Kellman, P., “Time Integrating Optical Signal Processing”, Ph. D.     Dissertation, Stanford University, 1979, pp. 51–55. -   Kelly et al. “Efficiency Issues Related to Probability Density     Function Comparison”, SPIE vol. 2670, pp. 42–49 January 1996. -   Kelly, P. M., et al. “Candid Comparison Algorithm for Navigating     Digital Image Databases”, Proceedings 7th International Working     Conference on Scientific and Statistical Database Management, pp.     252–258, 1994. -   Kim, D. H.; Caulfield, H. J.; Jannson, T.; Kostrzewski, A.; Savant,     G, “Optical fractal image processor for noise-embedded targets     detection”, Proceedings of the SPIE—The International Society for     Optical Engineering, Vol: 2026 p. 144–9 (1993) (SPIE Conf: Photonics     for Processors, Neural Networks, and Memories 12–15 July 1993, San     Diego, Calif., USA). -   Kim, Y., “Chips Deliver Multimedia”, Byte, December 1991, pp.     163–173. -   Knowlton, K., “Virtual Pushbuttons as a Means of Person-Machine     Interaction”, Proc of Conf. Computer Graphics, Pattern Recognition     and Data Structure, Beverly Hills, Calif., May 1975, pp. 350–352. -   Koch, H., “Ergonomische Betrachtung von Schreibtastaturen”, Humane     Production, 1, pp. 12–15 (1985). -   Kohonen, “Self-Organization & Memory”, Second Ed., 1988,     Springer-Verlag, pp. 199–209. -   Kolson, Ann, “Computer wimps drown in a raging sea of technology”,     The Hartford Courant, May 24, 1989, B1. -   Kortegaard, B. L., “PAC-MAN, a Precision Alignment Control System     for Multiple Laser Beams Self-Adaptive Through the Use of Noise”,     Los Alamos National Laboratory, date unknown. -   Kortegaard, B. L., “Superfine Laser Position Control Using     Statistically Enhanced Resolution in Real Time”, Los Alamos National     Laboratory, SPIE-Los Angeles Technical Symposium, Jan. 23–25, 1985. -   Kraiss, K. F., “Alternative Input Devices For Human Computer     Interaction”, Forschunginstitut Fuir Anthropotecahnik, Werthhoven,     F.R. Germany. -   Kraiss, K. F., “Neuere Methoden der Interaktion an der Schnittstelle     Mensch-Maschine”, Z.F. Arbeitswissenschaft, 2, pp. 65–70, 1978. -   Krajewski, M. et al, “Applicability of Smart Cards to Network User     Authentication”. Computing Systems, vol. 7, No. 1, 1994. -   Krajewski, M., “Concept for a Smart Card Kerberos”, 15th National     Computer Security Conference, October 1992. -   Krajewski, M., “Smart Card Augmentation of Kerberos, Privacy and     Security Research Group Workshop on Network and Distributed System     Security”, February 1993. -   Kraus, T. W., T. J. Myron, “Self-Tuning PID Controller Uses Pattern     Recognition Approach”, Control Engineering, pp. 106–111, June 1984. -   Kreifeldt, J. G., “A Methodology For Consumer Product Safety     Analysis”, The 3rd National Symposium on Human Factors in Industrial     Design in Consumer Products, August 1982, 175–184. -   Kreifeldt, John, “Human Factors Approach to Medical Instrument     Design”, Electro/82 Proceedings, 3/3/1–3/3/6. -   Ksienski et al., “Low Frequency Approach to Target Identification”,     Proc. of the IEEE, -   63(12):1651–1660 (December 1975). -   Kuo, C.-C. J. (ed), “Multimedia Storage and Archiving Systems”, SPIE     Proc. Vol. 2916 (Nov. 18–Nov. 22, 1996). -   Kuocheng, Andy Poing, and Ellingstad, Vernon S., “Touch Tablet and     Touch Input”, Interface '87, 327. -   Kurokawa, M., “An Approach to Retrieving Images by Using their     Pictorial Features”, IBM Research, Japan, September 1989. -   Kyburg, H. E., “Bayesian and non Bayesian evidential updating”,     Artificial Intelligence 31:271–293 (1987). -   Lampson, Butler; Abadi, Martin; Burrows, Michael; and Wobber,     Edward; “Authentication in Distributed Systems: Theory and     Practice”; ACM Transactions on Computer Systems; vol. 10, No. 4;     November, 1992; pp. 265–310. -   Landis, Sean, “Content-Based Image Retrieval Systems for Interior     Design”, http://www.tc.comell.edu/Visualization/Education/cs718/fall     1995/landis/index.html. -   Langton C G (ed): Artificial Life; Proceedings of the first     international conference on Artificial life, Redwood City:     Addison-Wessley (1989). -   Lauwerier, Hans: “Fractals—Images of Chaos”, Penguin Books, London,     1991. -   LeCun, Y. et al., “Handwritten Digit Recognition: Applications of     Neural.”, IEEE Comm. Magazine, November 1989, pp. 41–46. -   LeCun, Y., “Connectionism in Perspective”, in R. Pfeifer, Z.     Schreter. F. Fogelman, L. Steels (Eds.), 1989, “Generalization and     Network Design Strategies”, pp. 143–155. -   Ledgard, Henry, Singer, Andrew, and Whiteside, John, Directions in     Human Factors for Interactive Systems, New York, Springer-Verlag,     1981. -   Lee et al., “Video Indexing—An Approach based on Moving Object and     Track”. Proceedings of Storage and Retrieval for Image and Video     Databases, pp. 25–36. February 1993. -   Lee, Denis, et al., “Query by Image Content Using Multiple Objects     and Multiple Features: User Interface Issues,” 1994 Int'l Conf. on     Image Processing, IEEE. pp. 76–80. -   Lee, E., “Similarity Retrieval Techniques”, Pictorial Information     Systems, Springer Verlag, 1980 pp. 128–176. -   Lee, Eric, and MacGregor, James, “Minimizing User Search Time Menu     Retrieval Systems”, Human Factors, 27(2):157–162 (April 1986). -   Lee, S., et al, “2D C-string: A New Spatial Knowledge     Representatioor Image Database Systems”, Pattern Recognition, vol.     23, 1990, pp. 1077–1087. -   Lee, S., et al, “Similarity Retrieval of Iconic Image Database”,     Pattern Recognition, vol. 22, No. 6 1989, pp. 675–682. -   Lee, S., et al, “Spatial Reasoning and Similarity Retrieval of     Images Using 2D C-string Knowledge Representation”, Pattern     Recognition, 1992, pp. 305–318. -   Lendaris, G. G., and Stanely, G. L., “Diffraction Pattern Sampling     for Automatic Target Recognition”, Proc. IEEE 58:198–205 (1979). -   Leon, Carol Boyd, “Selling Through the VCR”, American Demographics,     December 1987, 40–43. -   Li, H. Y., Y. Qiao and D. Psaltis, Applied Optics (April, 1993). -   Liepins, G. E., M. R. Hilliard, “Genetic Algorithms: Foundations &     Applications”, Annals of Operations Research, 21:31–58 (1989). -   Lin, H. K., et al., “Real-Time Screen-Aided Multiple-Image Optical     Holographic Matched-Filter Correlator”, Applied Optics,     21(18):3278–3286 (Sep. 15, 1982). -   Liou, “Overview of the px64 kbit/s Video Coding Standard”,     Communications of the ACM, vol. 34, No. 4, April 1991, pp. 60–63. -   Lippmann, R. P., “An Introduction to Computing with Neural Nets”,     IEEE ASSP Magazine, 4(2):4–22 (April 1987). -   Liu, Y., “Extensions of fractal theory”, Proceedings of the SPIE—The     International Society for Optical Engineering, 1966:255–68(1993). -   Liu, Y., “Pattern recognition using Hilbert space”, Proceedings of     the SPIE—The International Society for Optical Engineering,     1825:63–77 (1992). -   Ljung, Lennart, & Torsten Soderstrom: “Theory and Practice of     Recursive Identification”, The MIT Press, Cambridge, Mass., 1983. -   Ljung, Lennart: “System Identification; Theory for the User”,     Prentice-Hall Englewood Cliffs, N.J., 1987. -   Lloyd, Sheldon G., & Gerald D Anderson: “Industrial Process     Control”, Fisher Controls Co., Marshalltown, 1971. -   Loeb, S., “Architecting Personalized Delivery of Multimedia     Information”, Communications of the ACM, December 1992, vol. 35, No.     12, pp. 39–50. -   Long, John, “The Effect of Display Format on the Direct Entry of     Numerical Information by Pointing”, Human Factors, 26(1):3–17     (February 1984). -   Lu, C., “Computer Pointing Devices: Living With Mice”, High     Technology, January 1984, pp. 61–65. -   Lu, C., “Publish It Electronically”, Byte, September 1993, pp.     94–109. -   Mackay et al., “Virtual Video Editing in Interactive Multimedia     Applications”, 1989. -   Mahalanobis, A., et al., “Minimum Average Correlation Energy     Filters”, Applied Optics, 26(17):3633–40 (Sep. 1, 1987). -   Makridakis, Spyros, & Steven Wheelwright: “The Handbook of     Forecasting”, John Wiley, New York, 1982. -   Mandelbrot, Benoit: “Fractal Geometry of Nature”, W H Freeman and     Co., New York, -   1983 (orig ed 1977). -   Mandelbrot, Benoit: “Fractals—Form, Chance and Dimensions”. W H     Freeman and Co., San Francisco, 1977. -   Manners, George, “Smart Screens; Development of Personal Navigation     Systems for TV Viewers,” Video Magazine, December 1993. -   Mannes, G., “Smart Screens”, Video Magazine. December 1993) (2     Pages). -   Mantei, Marilyn M., and Teorey, Toby J., “Cost/Benefit Analysis for     Incorporating Human Factors in the Software Lifecycle”. Association     for Computing Machinery, 1988. -   Maragos, P., “Tutorial Advances in Morphological Image Processing”     Optical Engineering 26:7:623–632 (1987). -   Mardia, K V, J T Kent & J M Bibby: “Multivariate Analysis”, Academic     Press, London, 1979. -   Martin, G. L. et al., “Recognizing Hand-Printed Letters and Digits     Using Backpropagation Learning”, Technical Report of the MCC, Human     Interface Laboratory, Austin, Tex., January 1990, pp. 1–9. -   Martinez et al. “Imagenet: A Global Distribution Database for Color     Image Storage and Retrieval in Medical Imaging Systems” IEEE, 1992,     710–719, May 1992. -   Masahiro Morita & Yoichi Shinoda, Information Filtering Based on     User Behavior Analysis and Best Match Text Retrieval, Proceedings of     the Seventeenth Annual International ACM-SIGIR Conference on     Research and Development in Information Retrieval, Dublin, Jul. 3–6,     1994, Paces Title Page (272)-281. -   Mazel, D. S., “Fractal Modeling of Time-Series Data”, PhD Thesis,     Georgia Tech, 1991. (One dimensional, not pictures). -   McAulay, A. D., J. C. Oh, “Image Learning Classifier System Using     Genetic Algorithms”, IEEE Proc. of the National Aerospace &     Electronics Conference, 2:705–710 (1989). -   McCauley, Joseph L.: “Chaos, Dymanics, and Fractals”, Cambridge     University Press, Cambridge, 1993. -   McFadden, M., “The Web and the Cookie Monster,” Digital Age. (1996,     August). -   Meads, Jon A., “Friendly or Frivolous”, Datamation, April 1, 1988,     98–100. -   Medvinsy et al, “NetCash: A Design for Practical Electronic Currency     on the Internet”, oc. 1st ACM Conf. on Comp. and Comm. Security,     November 1993. -   Medvinsy et al., “Electronic Currency for the Internet”, Electronic     Markets, pp. 30–31, September 1993. -   Mehrotra, R., et al, “Shape Matching Utilizing Indexed Hypotheses     Generation and Testing”,IEEE Transactions On Robotics, vol. 5; No.     1, February 1989, pp. 70–77. -   Meyer, J. A., Roitblat, H. L., Wilson, W. (eds.): From Animals to     Animats. Proceedings of the Second International Conference on     Simulation of Adaptive Behaviour. Cambridge, Mass.: MIT Press.     (1991). -   Middleton, G. V. ed., 1991, Nonlinear Dynamics, Chaos and Fractals,     with Applications to Geological Systems. Geol, Assoc. Canada Short     Course Notes Vol. 9 (available from the GAC at Memorial University     of Newfoundland, St. John's NF A1B 3×5). -   Miller et al., “News On-Demand for Multimedia Networks”. ACM     International Conference on Multimedia, Anaheim, Calif., 1–6, August     1993, pp. 383–392. -   Miller, R. K., Neural Networks ((c) 1989: Fairmont Press, Lilburn,     Ga.), pp. 2–12 and Chapter 4, “Implementation of Neural Networks”,     pp. 4-1 to 4-26. -   Mills et al., “A Magnifier Tool for Video Data”, Proceedings of ACM     Computer Human Interface (CHI), May 3–7, 1992, pp. 93–98. -   Mills, “Media Composition for Casual Users”, 1992. -   Minka, T., “An Image Database Browser that Learns from User     Interaction”, Masters Thesis, Massachusetts Institute of Technology;     1996; also appears as MIT Media Laboratory Technical Report 365. -   Minneman et al., “Where Were We: making and using near-synchronous,     pre-narrative video”, Multimedia '93, pp. 1–11. December 1993. -   Molley, P., “Implementing the Difference-Squared Error Algorithm     Using An Acousto-Optic Processor”, SPIE, 1098:232–239, (1989). -   Molley, P., et al., “A High Dynamic Range Acousto-Optic Image     Correlator for Real-Time Pattern Recognition”, SPIE, 938:55–65     (1988). -   Moloney, Daniel M.: Digital Compression in Todays Addressable     Enviroment; 1993 NCTA Technical Papers; Jun. 6, 1993; pp. 308–316. -   Monro D M and Dudbridge F, “Fractal block coding of images”,     Electronics Letters 28(11):1053–1054 (1992). -   Monro D. M. & Dudbridge F. ‘Fractal approximation of image blocks’,     Proc ICASSP 92, pp. III: 485–488. -   Monro D. M. ‘A hybrid fractal transform’, Proc ICASSP 93, pp. V:     169–72. -   Monro D. M., Wilson D., Nicholls J. A. ‘High speed image coding with     the Bath Fractal Transform’, IEEE International Symposium on     Multimedia Technologies Southampton, April 1993. -   Moore, G. and Dartnall, “Human Factors of a Microelectronic Product:     The Central Heating Timer/Programmer”, Applied Ergonomics, 1983,     13(1):15–23. -   Mori, “Towards the construction of a large-scale neural network”,     Electronics Information Communications Association Bulletin PRU     88-59, pp. 87–94. -   Nadoli, Gajanana and Biegel, John, “Intelligent Agents in the     Simulation of Manufacturing Systems”, Proceedings of the SCS     Multiconference on AI and Simulation, 1989. -   Nagasaka et al., “Automatic Video Indexing and Full-Video Search for     Object Appearances”, Proceedings of the IFIP TC2/WG2.6 Second     Working Conference on Visual Database Systems, North Holland, (Knuth     et al., eds.), Sep. 30-Oct. 3, 1991, pp. 113–127, January 1992. -   Naik et al., “High Performance Speaker Verification.”, ICASSP 86,     Tokyo, -   CH2243-4/86/0000-0881, IEEE 1986, pp. 881–884. -   National Westminster Bank Group Brochure; pp. 1–29; undated. -   Needham, Roger M. and Schroeder, Michael D.; “Using Encryption for     Authentication in Large Networks of Computers”; Communications of     the ACM; vol. 21, No. 12; December, 1978; pp. 993–999. -   Needham, Roger M.; “Adding Capability Access to Conventional File     Servers”; Xerox Palo Alto Research Center; Palo Alto, Calif. -   Negahdaripour, S., et al “Challenges in Computer Vision: Future     Research Direction”, IEEE Transactions On Systems, Man And     Cybernetics, pp. 189–199, 1992, at Conference on Computer Vision and     Pattern Recognition. -   Netravali, Arun N., and Haskell, Barry G., “Digital Pictures     Representation and Compression”, Plenum Press, New York (1988). -   Newman, B. C., “Proxy-Based Authorization and Accounting for     Distributed Systems”, Proc. 13th Int. Conf. on Dist. Comp. Sys., May     1993. -   NewMedia, November/December 1991, p. 69. -   Ney, H., et al., “A Data Driven Organization of the Dynamic     Programming Beam Search for Continuous Speech Recognition”, Proc.     ICASSP 87, pp. 833–836, 1987. -   Niblack, W. et al., “The QBIC Project: Querying Images by Content     Using Color, Texture, and Shape”, IBM Computer Science Research     Report, pp. 1–20 (Feb. 1, 1993). -   Niblack, W., et al, “Find me the Pictures that Look Like This: IBM'S     Image Query Project”, Advanced Imaging, April 1993, pp. 32–35. -   Niblack, W., R. Barber, W. Equitz, M. Flickner, E. Glasman, D.     Petkovic; P. Yanker, and C. Faloutsos. The QBIC project: Querying     images by content using color, texture, and shape. In Storage and     Retrieval for Image and eo Databases, volume SPIE Vol. 1908,     February 1993. -   Nilsson, B. A., “Microsoft Publisher is an Honorable Start for DTP     Beginners”, Computer Shopper, February 1992, vol. 12, Issue 2, p.     426, evaluates Microsoft Publisher and Page Wizard. -   Nilsson, N. J., The Mathematical Foundations of Learning Machines     ((c) 1990: Morgan Kaufmann Publishers, San Mateo, Calif.) and     particularly section 2.6 “The Threshold Logic Unit (TLU)”, pp. 21–23     and Chapter 6, “Layered Machines” pp. 95–114. -   Norman, D. A., Fisher, D., “Why Alphabetic Keyboards Are Not Easy To     Use: Keyboard Layout Doesn't Much Matter”, Human Factors 24(5), pp.     509–519 (1982). -   Norman, Donald A., “Infuriating By Design”, Psychology Today,     22(3):52–56 (March 1988). -   Norman, Donald A., The Psychology of Everyday Things, New York,     Basic Book, Inc. 1988. -   Novak et al., “Anatomy of a Color Histogram”, Proceeding of Computer     Vision and Pattern Recognition, Champaign, Ill., June 1992, pp.     599–605. -   Nussbaumer et al., “Multimedia Delivery on Demand: Capacity Analysis     and Implications”, Proc 19th Conference on Local Computer Networks,     2–5 Oct. 1994, pp. 380–386. -   O'Connor, Rory J., “Apple Banking on Newton's Brain”, San Jose     Mercury News, Wednesday, Apr. 22, 1992. -   O'Docherty, M. H., et al, “Multimedia Information System —The     Management and Semantic Retrieval of all Electronic Data Types”, The     Computer Journal, vol. 34, No. 3, 1991. -   Ohsawa, I. and Yonezawa, A., “A Computational Model of an     Intelligent Agent Who Talks with a Person”, Research Reports on     Information Sciences, Series C, April 1989, No. 92, pp. 1–18. -   Ohsuga et al, “Entrainment of Two Coupled van der Pol Oscillators by     an External Oscillation”, Biological Cybernetics, 51:225–239 (1985). -   Oien, G. E., S. Lepsoy & T. A. Ramstad, ‘An inner product space     approach to image coding by contractive transformations’, Proc.     ICASSP 1991, pp 2773–2776. -   Okada, Y., et al., “An Image Storage and Retrieval System for     Textile Pattern Adaptable to Color Sensation of the Individual”,     Trans. Inst. Elec. Inf. Comm., vol. J70D. No. 12, pp. 2563–2574,     December 1987 (Japanese w/English Abstract). -   Okamoto et al; “Universal Electronic Cash”, pp. 324–337; 1991. -   Omata et al, “Holonic Model of Motion Perception”. IEICE Technical     Reports, Mar. 26, 1988, pp. 339–346. -   O'Neal et al., “Coding Isotropic Images”, November 1977, pp.     697–707. -   Ono, Atsushi, et al., “A Flexible Content-Based Image Retrieval     System with Combined Scene Description Keyword,” Proc. of Multimedia     '96, IEEE, pp. 201–208. -   Optical Engineering 2 (May 1988) (Special Issue on product     inspection). -   Page, G F. J B Gomm & D Williams: “Application of Neural Networks to     Modelling and Control”, Chapman & Hall, London, 1993. -   Pandit, S. M., & S. M. Wu, “Timer Series & System Analysis with     Applications”, John Wiley & Sons, Inc., NY (1983) pp. 200–205. -   Pawlicki, T. F., D. S. Lee, J. J. Hull and S. N. Srihari, “Neural     Network Models and their Application to Handwritten Digit     Recognition,” ICNN Proceeding, 1988, pp. II-63–70. -   Pazzani, M. et al., “Learning from hotlists and coldlists: Towards a     WWW Information Filtering and Seeking Agent,” Proceedings     International Conference on Tools with Artificial Intelligence,     January 1995, pp. 492–495. -   Pecar, Branko: “Business Forecasting for Management”, McGraw-Hill     Book Co., London, 1994. -   Peitgen, Heinz-Otto, & Deitmar Saupe: “The Science of Fractal     Images”, Springer-Verlag, New York, 1988. -   Peitgen, Heinz-Otto, Hartmut Jurgens & Deitmar Saupe: “Fractals for     the Classroom”, Springer-Verlag, 1992. -   Perry et al., “Auto-Indexing Storage Device”, IBM Tech. Disc.     Bulletin, 12(8):1219 (January 1970). -   Perspectives: High Technology 2, 1985. -   Peters: “Chaos and Order in the Capital Markets”, Wiley, 1991.     Gershenfeld & Weigend: “The Future of Time Series”, Addison-Wesley,     1993. -   Peterson, Ivars, “Packing It In—Fractals.”, Science News,     131(18):283–285 (May 2, 1987). -   Peterson, Ivars: “The Mathematical Tourist”, W H Freeman, New York,     1988. -   Petrakis, E. G. M., and C. Faloutsos. Similarity searching in large     image databases. Technical Report 3388, Department of Computer     Science, University of Maryland, 1995. -   Pettit, Frank: “Fourier Transforms in Action”, Chartwell-Bratt,     Lund, 1985. -   Pfitzmann et al; “How to Break and Repair a Provably Secure     Untraceable Payment System”; pp. 338–350; 1991. -   Phillips, “MediaView: a general multimedia digital publication     system”, Comm. of the ACM, v. 34, n. 7, pp. 75–83. July 1991. -   Picard et al. “Finding Similar Patterns in Large Image Databases”,     IEEE, 1993, pp. 161–164, April 1993. -   Picard, R. W., et al, “finding Similar Patterns in Large Image     Databases”, IEEE ICASSP, Minneapolis, Minn., vol. V, pp. 161–164,     April 1993; also appears in MIT Media Laboratory Technical Report     No. 205. -   Pickover, Cliff, Visions of the Future: Art, Technology, and     Computing in the 21st Century (St. Martin's Press). -   Pickover, Cliff, Chaos in Wonderland: Visual Adventures in a Fractal     World (St. Martin's Press). -   Pickover, Cliff, Computers and the Imagination (St. Martin's Press). -   Pickover, Cliff, Computers, Pattern, Chaos, and Beauty (St. Martin's     Press). -   Pickover, Cliff, Frontiers of Scientific Visualization (Wiley). -   Pickover, Cliff, Mazes for the Mind: Computers and the Unexpected     (St. Martin's Press). -   Pickover, Cliff. Spiral Symmetry (World Scientific). -   Pizano, A., et al, “Communicating with Pictorial Databases”.     Human-Machine Interactive Systems, pp. 61–87, Computer Science Dept,     UCLA, 1991. -   Platte, Hans-Joachim. Oberjatzas, Gunter, and Voessing, Walter, “A     New Intelligent Remote Control Unit for Consumer Electronic Device”,     IEEE Transactions on Consumer Electronics, Vol. CE-31(1):59–68     (February 1985). -   Poor, Alfred, “Microsoft Publisher”, PC Magazine, Nov. 26, 1991,     vol. 10, Issue 20, p. 40, evaluates Microsoft Publisher. -   Port, Otis, “Wonder Chips-How They'll Make Computing Power Ultrafast     and Ultracheap”, Business Week, Jul. 4, 1994, pp. 86–92. -   Press, William H. et al, “Numerical Recipes in C The Art of     Scientific Computing”, Cambridge University Press, 1988. -   Price, R., et al., “Applying Relevance Feedback to a Photo Archival     System”, Journal of Information Science 18, pp. 203–215 (1992). -   Priebe, C. E.; Solka, J. L.; Rogers, G. W., “Discriminant analysis     in aerial images using fractal based features”, Proceedings of the     SPIE—The International Society for Optical Engineering,     1962:196–208(1993). -   PRNewswire, information concerning the PointCast Network (PCN)     (1996, Feb. 13) p. 213. -   Proakis, John G., Digital Communications, McGraw-Hill (1983). -   Proceedings of the IEEE, vol. 82, No.4, April 1994 New York, N.Y.,     US, pp. 585–589, XP 000451419 Miller “A Scenario for the Deployment     of Interactive Multimedia Cable Television Systems in the United     States in the 1990's”. -   Proceedings, 6th International Conference on Pattern Recognition     1982, pp. 152–136. -   Psaltis, D., “Incoherent Electro-Optic Image Correlator”, Optical     Engineering, 23(1):12–15 (January/February 1984). -   Psaltis, D., “Two-Dimensional Optical Processing Using     One-Dimensional Input Devices”, Proceedings of the IEEE,     72(7):962–974 (July 1984). -   Quinell, Richard A., “Web Servers in embedded systems enhance user     interaction”, EDN, Apr. 10, 1997, pp. 61–68. -   Raggett, D., “A review of the HTML+document format,” Computer     Networks and ISDN Systems, vol. 27, No. 2, pp. 35–145 (November     1994). -   Rahmati, M.; Hassebrook, L. G., “Intensity- and distortion-invariant     pattern recognition with complex linear morphology”, Pattern     Recognition, 27 (4):549–68(1994). -   Rampe, Dan, et al. In a Jan. 9, 1989 news release, Claris     Corporation announced two products, SmartForm Designer and SmartForm     Assistant, which provide “Intelligent Assistance”, such as custom     help messages, choice lists, and data-entry validation and     formatting. -   Rangan et al., “A Window-based Editor for Digital Video and Audio”,     January 1992. -   Rao et al., Discrete Cosine Transform—Algorithms, Advantages,     Applications, Academic Press, Inc., 1990. -   Ratcliffe, Mitch and Gore, Andrew, “Intelligent Agents take U.S.     Bows.”, MacWeek, Mar. 2, 1992, vol. 6, No. 9, p. 1. -   Ravichandran, G. and Casasent, D., “Noise and Discrimination     Performance of the MINACE Optical Correlation Filter”, Proc. SPIE     Technical Symposium, April 1990, Orlando Fla., 1471 (1990). -   Reimer, “Memories in my Pocket”, Byte, pp. 251–258, February 1991. -   Reiss, “The Revised Fundamental Theorem of Moment Invariants”, IEEE     Transactions on Pattern Analysis and Machine Intelligence, vol. 13,     No. 8, August 1991, pp. 830–834. -   Reitman, Edward: “Exploring the Geometry of Nature”, Windcrest     Books, Blue Ridge Summit, 1989. -   Reusens, E., “Sequence coding based on the fractal theory of     iterated transformations systems”, Proceedings of the SPIE—The     International Society for Optical Engineering,     2094(pt.1):132–40(1993). -   Rhodes, W., “Acousto-Optic Signal Processing: Convolution and     Correlation”, Proc. of the IEEE, 69(1):65–79 (January 1981). -   Richards et al., “The Interactive Island”, IEE Revies, July/August     1991 pp. 259–263. -   Richards J., and Casasent, D., “Real Time Hough Transform for     Industrial Inspection” Proc. SPIE Technical Symposium, Boston 1989     1192:2–21 (1989). -   Rivest, R.; “The MD5 Message-Digest Algorithm”; MIT Laboratory for     Computer Science and RSA Data Security, Inc.; April, 1992. -   Rivest, R. L. et al., “A Method for Obtaining Digital Signatures and     Public-Key Cryptosystems,” Laboratory for Computer Science,     Massachusetts Institute of Technology, -   Cambridge, Mass. -   Rivest, R. L.; Shamir, A. & Adleman, L.; “A Method for Obtaining     Digital Signatures and Public-Key Cryptosystems”, Communications of     the ACM, February 1978, vol. 21, No. 2, pp. 120–126. -   Robinson, G., and Loveless, W., “Touch-Tone’ Teletext—A Combined     etext-Viewdata System,” IEEE Transactions on Consumer Electronics,     vol. CE-25, No. 3, July 1979, pp. 298–303. -   Rogus, John G. and Armstrong, Richard, “Use of Human Engineering     Standards in Design”, Human Factors, 19(1): 15–23 (February 1977). -   Rohrer, C., & Clay Nesler, “Self-Tuning Using a Pattern Recognition     Approach”, Johnson Controls, Inc., Research Brief 228 (Jun. 13,     1986). -   Roizen, Joseph, “Teletext in the USA,” SMPTE Journal, July 1981, pp.     602–610. -   Rosch, Winn L., “Voice Recognition: Understanding the Master's     Voice”, PC Magazine, Oct. 27, 1987, 261–308. -   Rose, D. E.; Mander, R.; Oren, T., Ponceleon, D. B.; Salomon, G. &     Wong, Y. Y. “Content Awareness in a File System Interface     Implementing the Pile Metaphor for Organizing Information”, 16 Ann.     Int'l SIGIR '93, ACM, pp. 260–269. -   Rosenfeld, Azriel and Avinash C. Kak, Digital Picture Processing,     Second Edition, Volume 2, Academic Press, 1982. -   Roy, B., “Classements et choix en presence de points de vue     multiples”, R.I.R.O.-2eme annee-no. 8, pp. 57–75 (1968). -   Roy, B., “Electre III: un algorithme de classements fonde sur une     representation floue des preferences en presence de criteres     multiples”, Cahiers du CERO, 20(1):3–24 (1978). -   Rui, Yong, Huang, Thomas S., Chang, Shih-Fu, “Image Retrieval: Past     Present and Future”. -   Rui, Yong, Huang, Thomas S., Mehotra, Sharad, “Browsing and     retrieving Video Content in a Unified Framework”. -   Rui, Yong, Huang, Thomas S., Ortega, Michael, Mehotra, Sharad,     “Relevance Feedback: A Power Tool for Interactive Content-Based     Image Retrieval”. -   Rumeihart, D. E., & James L McClelland, Parallel Distributed     Processing, Explorations in Microstructure of Cognition, vol. 1,     (1986: MIT Press, Cambridge, Mass.), and specifically Chapter 8     thereof, “Learning Internal Representations by Error Propagation”,     pp. 318–362. -   Rutherford, H. G., F. Taub and B. Williams, “Object Identification     and Measurement from Images with Access to the Database to Select     Specific Subpopulations of Special Interest”, May 1986. -   Rutter et al., “The Timed Lattice—A New Approach To Fast Converging     Equalizer Design”, pp.VIII/1–5 (Inspec. Abstract No. 84C044315,     Inspec IEE (London) & IEE Saraga Colloquium on Electronic Filters,     May 21, 1984). -   Sadjadi, F., “Experiments in the use of fractal in computer pattern     recognition”, Proceedings of the SPIE—The International Society for     Optical Engineering, 1960:214–22(1993). -   Sakoe, H., “A Generalization of Dynamic Programming Based Pattern     Mating Algorithm Stack DP-Matching”, Transactions of the Committee     on Speech Research, The Acoustic Society of Japan, p. S83–23, 1983. -   Sakoe, H., “A Generalized Two-Level DP-Matching Algorithm for     Continuous Speech Recognition”, Transactions of the IECE of Japan,     E65(11):649–656 (November 1982). -   Salomon et al, “Using Guides to Explore Multimedia Databases”, PROC     of the Twenty-Second Annual Hawaii International Conference on     System Sciences. vol. IV, 3–6 January 1989, pp. 3–12 vol. 4. Jan. 6,     1989. -   Salton, G., “Developments in Automatic Text Retrieval”, Science,     vol. 253, pp. 974–980, Aug. 30, 1991. -   Samet, H.; The quadtree and related hierarchical data structures.     ACM Computing Surveys, 16(2):187–260, 1984. -   Sarver, Carleton, “A Perfect Friendship”, High Fidelity, 39:42–49     (May 1989). -   Schamuller-Bichl, I., “IC-Cards in High-Security Applications”, in     Selected Papers from the Smart Card 2000 Conference, Springer     Verlag, 1991, pp. 177–199. -   Scharlic, A., “Decider sur plusieurs criteres. Panorama de l'aide a     la decision mukticritere” Presses Polytechniques Romandes (1985). -   Schied, Francis, “Shaum's Outline Series-Theory & Problems of     Numerical Analysis”, McGraw-Hill Book Co., NY (1968) pp. 236, 237,     243, 244, 261. -   Schmitt, Lee, “Let's Discuss Programmable Controllers”, Modern     Machine Shop, May 1987, 90–99. -   Schniederman, Ben, Designing the User Interface: Strategies for     Effective Human-Computer Interaction, Reading, Mass.,     Addison-Wesley, 1987. -   Schroeder, M., Fractals, Chaos, Power Laws, W.H. Freeman & Co., New     York (1991). -   Schurmann, J., “Zur Zeichen und Worterkennung beim Automatischen     Anschriftenlesen”, Wissenschaftlichl, Berichte, 52(1/2) (1979). -   Scientific American; “Not Just a Pretty Face”; March 1990, pp.     77–78. -   Seborg, D. E., T. F. Edgar, & D. A. Mellichamp, “Process Dynamics     and Control”, John Wiley & Sons, NY (1989) pp. 294–307, 538–541. -   Shafer, G., “A mathematical theory of evidence”, Princeton     University Press, Princeton, N.J. (1976). -   Shann et al. “Detection of Circular Arcs for Content-Based Retrieval     from an Image Database” IEE Proc.-Vis. Image Signal Process, vol.     141, No. 1, February 1994, pp. 49–55. -   Shardanand, Upendra, “Social Information Filtering for Music     Recommendation” September 1994, pp. 1–93, Massachusetts Institute of     Technology, Thesis. -   Sharif Heger, A. and Koen, B. V., “KNOWBOT: an Adaptive Data Base     Interface”, Nuclear Science and Engineering, February 1991, vol.     107, No. 2, pp. 142–157. -   Sharpless, “Subscription teletext for value added services”, August     1985. -   Shepard, J. D., “Tapping the Potential of Data Compression”,     Military and Aerospace00v1P Electronics, May 17, 1993, pp. 25–27. -   Sheth et al., “Evolving Agents for Personalized Information     Filtering”, 1–5 March 1993, pp. 345–352. -   Sheth, B. & Maes, P. “Evolving Agents For Personalized Information     Filtering”, Proc. 9th IEEE Conference, 1993 pp. 345–352. -   Shimizu et al, “Principle of Holonic Computer and Holovision”,     Journal of the Institute of Electronics, Information and     Communication, 70(9):921–930 (1987). -   Shinan et al., “The Effects of Voice Disguise.”, ICASSP 86, Tokyo,     CH2243-4/86/0000-0885, IEEE 1986, pp. 885–888. -   Silverston et al., “Spectral Feature Classification and Spatial     Pattern Rec.”, SPIE 201:17–26, Optical Pattern Recognition (1979). -   Simpson, W. R., C. S. Dowling, “WRAPLE: The Weighted Repair     Assistance Program Learning Extension”, IEEE Design & Test, 2:66–73     (April 1986). -   Sincoskie, W. D. & Cotton C. J. “Extended Bridge Algorithms for     Large Networks”, IEEE Network, January 1988-vol. 2, No. 1, pp.     16–24. -   Sirbu, Marvin A.; Internet Billing Service Design And Prototype     Implementation; pp. 1–19; An Internet Billing Server. -   Smith et al., “A New Family of Algorithms for Manipulating     Compressed Images”, IEEE Computer Graphics and Applications, 1993.     Smith, J. et al., “Quad-Tree Segmentation for Texture-Based Image     Query” Proceeding ACM Multimedia 94, pp. 1–15, San Francisco, 1994. -   Smith, J. R., and S.-F. Chang. Querying by color regions using the     VisualSEEk content-based visual query system. In M. T. Maybury,     editor, Intelligent Multimedia Information Retrieval. IJCAI, 1996. -   Smith, J. R., and S.-F. Chang. Tools and techniques for color image     retrieval. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     volume 2670, San Jose, Calif., February 1996. IS&T/SPIE. -   Smith, Sidney J., and Mosier, Jane N., Guidelines for Designing User     Interface Software, Bedford, Mass., MITRE, 1986. -   Smoliar, S. et al., “Content-Based Video Indexing and Retrieval”,     IEEE Multimedia, pp. 62–72 (Summer 1994). -   Society for Worldwide Interbank Financial Telecommunications S.C.,     “A.S.W.I.F.T. Overview”, undated. -   Soffer, A., and H. Samet. Retrieveal by content in symbolic-image     databases. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     pages 144–155. IS&T/SPIE, 1996. -   Soviero, Marce M., “Your World According to Newton”. Popular     Science, September 1992, pp. 45–49. -   Specht, IEEE Internatl. Conf. Neural Networks, 1:1525–1532 (July     1988), San Diego, Calif. -   Sperling, Barbara Bied, Tullis Thomas S., “Are You a Better ‘Mouser’     or ‘Trackballer’? A Comparison of Cursor—Positioning Performance”,     An Interactive/Poster Session at the CHI+GI'87 Graphics Interface     and Human Factors in Computing Systems Conference. -   Sprageu, R. A., “A Review of Acousto-Optic Signal Correlators”,     Optical Engineering, 16(5):467–74 (September/October 1977). -   Sprinzak, J.; Werman, M., “Affine point matching”, Pattern     Recognition Letters, 15(4):337–9(1994). -   Stanchev, P., et al, “An Approach to Image Indexing of Documents”,     Visual Database Systems, II, 1992, pp. 63–77. -   Stanley R. Stemberg, “Biomedical Image Processing”, IEEE Computer,     1983, pp. 22–34. -   Stark, J., “Iterated function systems as neural networks”, Neural     Networks, Vol 4, pp 679–690, Pergamon Press, 1991. -   Stevens, “Next Generation Network and Operating System Requirements     for Continuous Time Media”, in Herrtwich (Ed.), Network and     Operating System Support for Digital Audio and Video, pp. 197–208,     November 1991. -   Stewart, R. M., “Expert Systems For Mechanical Fault Diagnosis”,     IEEE, 1985, pp. 295–300. -   Streeter, L. A., Ackroff, J. M., and Taylor, G. A. “On Abbreviating     Command Names”, The Bell System Technical Journal, 62(6):1807–1826     (July/August 1983). -   Stricker, M., and A. Dimai. Color indexing with weak spatial     constraints. In Symposium on Electronic Imaging: Science and     Technology—Storage & Retrieval for Image and Video Databases IV,     pages 29–41. IS&T/SPIE, 1996. -   Stricker, M., and M. Orengo. Similarity of color images. In Storage     and Retrieval for Image and Video Databases III, volume SPIE Vol.     2420, February 1995. -   Sugeno, M., “Theory of fuzzy integrals and its applications”, Tokyo     Institute of Technology (1974). -   Svetkoff et al.; Hybrid Circuits (GB), No. 13, May 1987; pp. 5–8. -   Swain et al., “Color Indexing”, International Journal of Computer     Vision, vol. 7, No. 1, 1991, pp. 11–32. -   Swanson, David, and Klopfenstein, Bruce, “How to Forecast VCR     Penetration”, American Demographic, December 1987, 44–45. -   Tak W. Yan & Hector Garcia-Molina, SIFT —A Tool for Wide-Area     Information Dissemination, 1995 USENIX Technical Conference, New     Orleans, La., Jan. 16–20, pp. 177–186. -   Tamura, H., et al, “Image Database Systems: A Survey”, Pattern     Recognition, vol. 17, No. 1, 1984, pp. 29–34. -   Tamura, H., et al., “Textural Features Corresponding to Visual     Perception,” IEEE Transactions on System, Man, and Cyb., vol. SMC-8,     No. 6, pp. 460–473 (1978). -   Tanaka, S., et al, “Retrieval Method for an Image Database based on     Topological Structure”, SPIE, vol. 1153, 1989, pp. 318–327. -   Tanton, N. E., “UK Teletext—Evolution and Potential,” IEEE     Transactions on Consumer Electronics, vol. CE-25, No. 3, July 1979,     pp. 246–250. -   TCC Tech Facts, Vols. 1–4, (www.wgbh.org, rev. Sep. 1995). -   Television Decoder Circuitry Act of 1990, and Section 305 of the     Telecommunications Act of 1996, and FCC regulations. -   Tello, Ernest R., “Between Man And Machine”, Byte, September 1988,     288–293. -   Tenenbaum, Jay M. and Schiffman, Allan M.; “Development of Network     Infrastructure and Services for Rapid Acquisition”; adapted from a     white paper submitted to DARPA by MCC in collaboration with EIT and     ISI. -   Thomas, John, C., and Schneider, Michael L., Human Factors in     Computer Systems, New Jersey, Ablex Publ. Co., 1984. -   Thomas, William L., “Electronic Program Guide Applications—The     Basics of System Design”, 1994 NCTA Technical Papers, pp. 15–20. -   Tonomura et al., “Content Oriented Visual Interface Using Video     Icons for Visual Database Systems”, Journal of Visual Languages and     Computing (1990) 1, pp. 183–198. -   Tonomura et al., “VideoMAP and VideoSpaceIcon: Tools for Anatomizing     Video Content”, Inter CHI'93 Conference Proceedings, Amsterdam, The     Netherlands, 24–29 April, 1993, pp. 131–136. -   Tortora, G., et al, “Pyramidal Algorithms”, Computer Vision,     Graphics and Images Processing, 1990, pp. 26–56. -   Trachtenberg, Jeffrey A., “How do we confuse thee? Let us count the     ways”, Forbes, Mar. 21, 1988, 159–160. -   Training Computers To Note Images, New York Times, Apr. 15, 1992. -   Turcotte, Donald L., 1992, Fractals and Chaos in Geology and     Geophysics. Cambridge U.P. -   TV Communications Advertisement for MSI Datacasting Systems, January     1973. -   Tyldesley, D. A., “Employing Usability Engineering in the     Development of Office Products”, The Computer Journal”,     31(5):431–436 (1988). -   Udagawa, K., et al, “A Parallel Two-Stage Decision Method for     Statistical Character Recognition.”, Electronics and Communications     in Japan (1965). -   Ueda et al., “Automatic Structure Visualization for Video Editing”,     InterCHI'93 Conference Proceedings, Amsterdam, The Netherlands,     24–29 April 1993, pp. 137–141. -   Ueda al., “Impact: An Interactive Natural-Motion-Picture Dedicated     Multimedia Authoring System”, Proceedings of Human Factors in     Computing Systems (CHI 91), New Orleans, La., Apr. 27–May 2, 1991,     pp. 343–350. -   van den Boom, Henrie: An Interactive Videotex System for Two-Way     CATV Networks; AEU, Band 40; 1986; pp. 397–401. -   Vander Lugt, A., “Practical Considerations for the Use of Spatial     Carrier-Frequency Filters”, Applied Optics, 5(11):1760–1765     (November 1966). -   Vander Lugt, A., “Signal Detection By Complex Spatial Filtering”,     IEEE Transactions On Information Theory, IT-10, 2:139–145 (April     1964). -   Vander Lugt, A., et al.; “The Use of Film Nonlinearites in Optical     Spatial Filtering”; Applied Optics; 9(1):215–222 (January 1970). -   Vannicola et al, “Applications of Knowledge based Systems to     Surveillance”, Proceedings of the 1988 IEEE National Radar     Conference, 20–21 April 1988, pp. 157–164. -   Varela, F. J., and P. Bourgine (eds.): Proceedings of the first     European Conference on Artificial Life. Cambridge, Mass.: MIT Press.     (1991). -   Verplank, William L., “Graphics in Human-Computer Communication:     Principles of Graphical User-Interface Design”, Xerox Office     Systems. -   Vitols, “Hologram Memory for Storing Digital Data”, IBM Tech. Disc.     Bulletin 8(11):1581–1583 (April 1966). -   Vittal, J., “Active Message Processing: Message as Messengers”, pp.     175–195; 1981. -   Voydock, Victor et al.; “Security Mechanisms in High-Level Network     Protocols”; Computing Surveys; vol. 15, No. 2; June 1981. -   Voyt, Carlton F., “PLC's Learn New Languages”, Design News, Jan. 2,     1989, 78. -   Vrscay, Edward R. “Iterated Function Systems: Theory, Applications,     and the Inverse Problem.” Fractal Geometry and Analysis, J. Belair     and S. Dubuc (eds.) Kluwer Academic, 1991, 405–468. -   Wachman, J., “A Video Browser that Learns by Example”, Masters     Thesis, Massachusetts Institute of Technology; 1996; also appears as     MIT Media Laboratory Technical Report No. 383. -   Wakimoto, K., et al, “An Intelligent User Interface to an Image     Database using a Figure interpretation Method”, IEEE Publication No.     CH2898-5/90/0000/0516, 1990, pp. 516–520. -   Wald; Sequential Analysis; Dover Publications Inc., 1947; pp. 34–43. -   Wallace, “The JPEG Still Picture Compression Standard”,     Communications of the ACM, vol. 34, No. 4, April 1991, pp. 31–44. -   Wasserman, Philip, “Neural Computing-Theory & Practice”, 1989, pp.     128–129. -   Weber et al., “Marquee: A Tool for Real-Time Video Logging”, CHI     '94. April 1994. -   Weber, Thomas E., “Software Lets Marketers Target Web Ads,” The Wall     Street Journal, Apr. 21, 1997 -   Weiman, Liza and Moran, Tom, “A Step toward the Future”, Macworld,     August 1992, pp. 129–131. -   Weshsler, H. Ed., “Neural Nets For Human and Machine Perception”,     Academic Press, New York (1991). -   Whitefield, A. “Human Factors Aspects of Pointing as an Input     Technique in Interactive Computer Systems”, Applied Ergonomics, June     1986, 97–104. -   Wiedenbeck, Susan, Lambert, Robin, and Scholtz, Jean, “Using     Protocol Analysis to Study the User Interface”, Bulletin of the     American Society for Information Science, June/July 1989, 25–26. -   Wilf, Itzhak, “Computer, Retrieve For Me the Video Clip of the     Winning Goal”, -   Advanced Imaging, August 1998, pp. 53–55. -   Wilke, William, “Easy Operation of Instruments by Both Man and     Machine”. Electro/82 Proceedings, 3/2/1–3/2/4. -   Willett, P., “Recent Trends in Hierarchic Document Clustering: A     Critical Review”, Information Processing & Management, vol. 24, No.     5, pp. 557–597, 1988. -   Willshaw et al., “Non-Holographic Associative Memory”, Nature,     222:960–962 (Jun. 7, 1969). -   Woolsey, K., “Multimedia Scouting”, IEEE Computer Graphics And     Applications, July 1991 pp. 26–38. -   Yager, R. R., “Entropy and specificity in a mathematical theory of     Evidence”, Int. J. General Systems, 9:249–260 (1983). -   Yamada et. al., “Character recognition system using a neural     network”, Electronics Information Communications Association     Bulletin PRU 88–58, pp. 79–86. -   Yamamoto, A., et al, “Extraction of Object Features from Image and     its Application to Image Retrieval”, IEEE 9th International     Conference On Pattern Recognition, vol. 2, 1988, 988–991. -   Yamamoto, A., et al, “Image Retrieval System Based on Object     Features”, IEEE Publication No. CH2518-9/87/0000-0132, 1987, pp.     132–134. -   Yamamoto, A., et al., “Extraction of Object Features and Its     Application to Image Retrieval”, Trans. of IEICE, vol. E72, No. 6,     771–781 (June 1989). -   Yamane et al., “An Image Data Compression Method Using     Two-Dimensional Extrapolative Prediction-Discrete Sine Transform”,     Oct. 29–31, 1986, pp. 311–316. -   Yan et al., “Index Structures for Information Filtering Under the     Vector Space Model”, PROC the 10th International Conference on Data     Engineering, pp. 14–18 of DRD203RW User's Manual relating to the DSS     Digital System. -   Yan, T. W. and Garcia-Molina, H., “SIFT —A Tool for Wide-Area     Infortion Dissemination,” Paper presented at the USENIX Technical     Conference., New Orleans, La. (1995, January), pp. 177–186. -   Yoder, Stephen Kreider, “U.S. Inventors Thrive at Electronics Show”,     The Wall Street Journal, Jan. 10, 1990, B1. -   Yoshida, J., “The Video-on-demand Demand”, Electronic Engineering     Times, Mar. 15, 1993, pp. 1, 72. -   Yoshida, Y., et al, “Description of Weather Maps and Its Application     to Implementation of Weather Map Database”, IEEE 7th International     Conference On Pattern Recognition, 1984, pp. 730–733. -   Zadeh, L. A., “Fuzzy sets as a basis for a theory of possibility”,     Fuzzy sets and Systems 1:3–28 (1978). -   Zadeh, L. A., “Fuzzy sets”, Information and Control, 8:338–353     (1965). -   Zadeh, L. A., “Probability measures of fuzzy events”, Journal of     Mathematical Analysis and Applications, 23:421–427 (1968). -   Zeisel, Gunter, Tomas, Philippe, Tomaszewski, Peter, “An Interactive     Menu-Driven Remote Control Unit for TV-Receivers and VC-Recorders”,     IEEE Transactions on Consumer Electronics, 34(3):814–818. -   Zenith Starsight Telecast brochure, (1994). -   Zhang et al., “Developing Power Tools for Video Indexing and     Retrieval”, Proceedings of SPIE Conference on Storage and Retrieval     for Image and Video Databases, San Jose, Calif., 1994. -   Zhang, X., et al, “Design of a Relational Image Database Management     System: IMDAT”, IEEE Publication No. TH0166-9/87/0000-0310, 1987,     pp. 310–314. -   Zhi-Yan Xie; Brady, M., “Fractal dimension image for texture     segmentation”, ICARCV '92. Second International Conference on     Automation, Robotics and Computer Vision, p. CV-4.3/1–5 vol. 1,     (1992). -   Zhu. X., et al., “Feature Detector and Application to Handwritten     Character Recognition”, International Joint Conference on Neural     Networks, Washington, D.C., January 1990, pp. II-457 to II-460. -   Zhuang, Yueting, Rui, Yong, Huang, Thomas S., Mehotra. Sharad,     “Applying Semantic Association to Support Content-Based Video     Retrieval”. 

1. An apparatus for processing digital media signals, comprising: (a) a digital processor for controlling said apparatus; (b) a graphic user interface, receiving a wireless remote control graphic user interface input to said processor and outputting information for generating a graphic user interface display; (c) a network interface for transmitting digital information from said processor to a remote location over a communications network, said information identifying a desired digital media signal for reproduction based, at least in part, on an input received from said input; and (d) an output, controlled by, and local to, said processor, for transmitting the desired digital media signal for reproduction thereof.
 2. The apparatus according to claim 1, wherein said network interface comprises an Ethernet interface.
 3. The apparatus according to claim 1, wherein said network interface comprises a wireless local area network interface.
 4. The apparatus according to claim 1, wherein said network interface employs digitally modulated communications over a telephone subscriber line.
 5. The apparatus according to claim 1, wherein said network interface further communicates information describing the content of the digital media signals.
 6. The apparatus according to claim 1, further comprising a digital media data storage system, said data storage system hosting digital media in a retrievable format.
 7. The apparatus according to claim 6, wherein said digital media data storage system comprises an optical data storage medium.
 8. The apparatus according to claim 6, wherein said digital media data storage system comprises a rewritable optical data storage medium.
 9. The apparatus according to claim 6, wherein said digital media data storage system comprises a magnetic data storage medium.
 10. The apparatus according to claim 6, wherein said digital media data storage system comprises a semiconductor memory data storage medium.
 11. The apparatus according to claim 1, wherein said processor comprises a manager for limiting reproduction of digital media signals according to a defined right of reproduction, and wherein said output transfers digital media signals according to limits imposed by said manager.
 12. The apparatus according to claim 11, wherein said processor controls said output to distort the digital media signals in dependence on said manager.
 13. The apparatus according to claim 11, wherein said rights manager controls said output to prevent presentation of the digital media signals in dependence on said manager.
 14. The apparatus according to claim 1, wherein said output transfers the digital media signals as an analog media signal stream.
 15. The apparatus according to claim 1, wherein said output transfers the digital media signals as a digital media signal stream.
 16. The apparatus according to claim 1, wherein said wireless remote control comprises a visual display presenting data based, at least in part, on a communication from said processor.
 17. The apparatus according to claim 1, wherein said network interface communicates an electronic program guide information.
 18. The apparatus according to claim 1, wherein said remote control communicates through said network interface.
 19. The apparatus according to claim 1, wherein said identifying a desired digital media signal for reproduction comprises referencing an index.
 20. The apparatus according to claim 1, wherein said network interface communicates IP packets.
 21. The apparatus according to claim 1, wherein said communications network comprises fiber optics.
 22. The apparatus according to claim 1, wherein said network interface comprises at least one of 10-Base T, 100-Base T, HomeRun®, Universal Serial Bus, and Firewire® (IEEE-1394).
 23. The apparatus according to claim 1, further comprising a remote control having a direct manipulation directional user input.
 24. The apparatus according to claim 1, further comprising a remote control having a graphic display.
 25. An apparatus for processing media signals, comprising: (a) a programmable processor for controlling said apparatus, and providing a graphical user interface, said programmable processor being adapted to receive a graphic user interface input and generating a graphic user interface display; (b) an interface for transmitting digital information from said programmable processor to a remote location, said information identifying at least one digital media signal from a set of available digital media signals, based, at least in part, on an input to said graphic user interface; and (c) an output from the programmable processor for transferring the identified digital media signal.
 26. The apparatus according to claim 25, wherein said graphic user interface input is received from a wireless remote control.
 27. The apparatus according to claim 25, wherein the digital media selectively signals are received from a remote location to the programmable processor in response to the transmitted digital information.
 28. The apparatus according to claim 25, wherein the transmitted digital information is used at the remote location to account for a transfer of the digital media signals from the programmable processor.
 29. The apparatus according to claim 25, wherein the graphic user interface is of a direct manipulation type and wherein data defining the graphic user interface display is transferred through a common output with the digital media signals to provide an on-screen display.
 30. The apparatus according to claim 25, wherein said programmable processor is adapted to receive and execute non-media related graphic user interface software.
 31. An apparatus for controlling media program presentation, comprising: (a) a digital processor; (b) at least one media output controlled by, and local to, said digital processor, for defining a set of choices to a user for selection thereof, and transferring a selected media program for presentation to a user; (c) a wireless remote control providing a command input from the user to said processor; and (d) an interface for transmitting digital information from said processor to a remote location over a communications network, said information relating to a desired media program for transfer based, at least in part, on an input received from said wireless remote control.
 32. The apparatus according to claim 31, wherein said interface comprises an Internet interface.
 33. The apparatus according to claim 31, wherein said media output comprises a graphic user interface and said wireless remote control comprises a cursor control.
 34. The apparatus according to claim 31, wherein a desired media program is determined inferentially.
 35. An apparatus for processing digital media signals, comprising: (a) a digital processor for controlling said apparatus and generating a graphic user interface, and receiving a pointing device input; (b) a network interface for transmitting digital information from said processor to a remote location over a communications network, said information identifying a desired digital media signal based, at least in part, on an input received from said pointing device input, and (c) an output, controlled by, and local to, said processor, for transferring the desired digital media signal for reproduction thereof.
 36. The apparatus according to claim 35, wherein said network interface comprises a packet data network interface.
 37. The apparatus according to claim 35, wherein said network interface comprises a fiber optic.
 38. The apparatus according to claim 35, wherein said network interface comprises an Internet Protocol network.
 39. The apparatus according to claim 35, further comprising a digital media data storage system which stores digital media in a retrievable format for reproduction of the media content thereof.
 40. The apparatus according to claim 35, wherein said digital media data storage system comprises at least one of an optical data storage medium, a magnetic data storage medium, and a semiconductor data storage medium.
 41. The apparatus according to claim 35, wherein said digital processor comprises a manager for limiting reproduction of digital media signals according to a defined right of reproduction, and wherein said output restricts digital media signals according to limits imposed by said manager.
 42. The apparatus according to claim 35, wherein said network interface communicates electronic program guide information to said digital processor. 